Methods for use in combination for the treatment and diagnosis of autoimmune diseases

ABSTRACT

This disclosure provides new genetic targets, diagnostic methods, and therapeutic treatment regimens for multiple autoimmune disorders, including pediatric autoimmune disorders that are co-inherited and genetically shared. The disclosure, for example, provides methods of diagnosing or determining a susceptibility for one or more autoimmune diseases and methods of determining treatment protocols for patients with one or more autoimmune diseases based on determining if the patients have genetic alterations in particular genes.

PRIORITY APPLICATIONS

This application claims priority to U.S. Provisional Application No. 62/208,383, filed Aug. 21, 2015, and 62/320,400, filed Apr. 8, 2016, both of which are incorporated by reference herein in their entirety.

GRANT STATEMENT

This invention was made with funds from the National Institutes of Health, Grant Nos. DP3DK085708, RC1AR058606, U01HG006830, CA127334, and R01-HG006849. Accordingly, the United States Government has rights in this invention.

FIELD OF THE INVENTION

This invention relates to the fields of genetics, autoimmunity and personalized medicine. More specifically the invention provides new genetic targets, diagnostic methods, and therapeutic treatment regimens for multiple autoimmune disorders, including pediatric autoimmune disorders.

BACKGROUND OF THE INVENTION

Several publications and patent documents are cited throughout the specification in order to describe the state of the art to which this invention pertains. Each of these citations is incorporated by reference herein as though set forth in full. Color versions of certain figures and tables included herein have also been published in Y. R. Li et al, Nature Medicine Aug. 24, 2015, online publication doi: 10.1038 “backslash” nm.3933, and in the supplemental materials for that publication, and those figures and tables are incorporated by reference herein.

Autoimmune diseases affect up to 7-10% of individuals living in the Western Hemisphere¹, representing a significant cause of chronic morbidity and disability. High rates of autoimmune disease comorbidity and familial clustering suggest that a strong genetic predisposition may underlie autoimmune disease susceptibility. Genome-wide association studies (GWAS) and immune-focused fine-mapping studies of autoimmune thyroiditis (AITD)², psoriasis (PSOR)³, juvenile idiopathic arthritis (JIA)⁴, primary biliary cirrhosis (PBC)⁵, primary sclerosing cholangitis (PSC)⁶, rheumatoid arthritis (RA)⁷, celiac disease (CEL)⁸, inflammatory bowel disease (IBD, which includes Crohn's Disease (CD) and ulcerative colitis (UC)⁹), and multiple sclerosis (MS), have identified hundreds of autoimmune disease-associated single-nucleotide polymorphisms (SNPs) across the genome¹⁰. These studies and subsequent meta-analyses demonstrate that over half of all genome-wide significant (GWS) (P_(GWS)<5×10⁻⁸) autoimmune disease associations are shared by at least two distinct autoimmune diseases^(11,12). However, when applied to heterogeneous diseases, classical meta-analysis approaches face limitations as they: 1) have limited power when disease-associated variants show variable effect sizes or even directions of effect across the traits, 2) may be affected by phenotypic heterogeneity and subject recruitment bias across studies, 3) often examine a candidate list or previously-discovered loci from single-disease studies, thereby missing the chance to identify novel associations, particularly those due to variants that are rarer or have smaller effect sizes, 4) do not fully adjust for population stratification and cryptic relatedness, and 5) may contain artifacts introduced by the use of multiple genotyping platforms or study sites.

While a few studies have merged case genotypes from multiple diseases in a limited way¹³⁻¹⁵, and a few loci have surfaced in independent GWAS studies across multiple autoimmune diseases, such as CLEC16A, first discovered in T1D¹⁶, and subsequently in MS¹⁷, RA^(18,19), CD²⁰, PBC²¹, JIA¹⁹, and AA²², the degree to which genetic variants associated with one disease may be associated with the risk of other autoimmune diseases has not been systematically examined. Clearly, having this information would provide new therapeutic avenues for the treatment of such disorders.

SUMMARY OF THE INVENTION

In accordance with the present invention, new genetic markers are provided for the diagnosis and treatment of autoimmune disease (AID), which includes, for example, pediatric autoimmune disease (pAID). Autoimmune diseases discussed herein include, for example, one or more of ankylosing spondylitis (AS), psoriasis (PS or PSOR), celiac disease (CEL), systemic lupus erythematosus (SLE), common variable immunodeficiency (CVID), inflammatory bowel disease (IBD) ulcerative colitis (UC), type I diabetes (T1D), juvenile idiopathic arthritis (JIA), Crohn's disease (CD), alopecia areata (AA), multiple sclerosis (MS), primary biliary cirrhosis (PBC), primary sclerosing cholangitis (PSC), rheumatoid arthritis (RA), Sjogren's syndrome (SJO), systemic sclerosis (SSC), spondyoarthropathy (SPA), vitiligo (VIT), asthma, or thyroiditis (AITD, THY or TH), as well as several others.

For example, included herein is a method for diagnosing one or more autoimmune disorders (AID) in a patient, comprising: a) obtaining a biological sample from the patient; b) assaying nucleic acid from the sample to determine whether a genetic alteration in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX is present, wherein a genetic alteration in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX is correlated with presence of one or more AID in the patient; and c) diagnosing the patient with one or more AID if a genetic alteration is present in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX.

In some embodiments, the method comprises determining whether a genetic alteration is present in at least 5, such as at least 10, such as at least 15, such as at least 20, such as at least 25, such as at least 30, such as at least 35, such as at least 40, or in each of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, § EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX. In some embodiments, the AID is one or more of ankylosing spondylitis (AS), psoriasis (PS or PSOR), celiac disease (CEL), systemic lupus erythematosus (SLE), common variable immunodeficiency (CVID), inflammatory bowel disease (IBD) ulcerative colitis (UC), type I diabetes (T1D), juvenile idiopathic arthritis (JIA), Crohn's disease (CD), alopecia areata (AA), multiple sclerosis (MS), primary biliary cirrhosis (PBC), primary sclerosing cholangitis (PSC), rheumatoid arthritis (RA), Sjogren's syndrome (SJO), systemic sclerosis (SSC), spondyoarthropathy (SPA), vitiligo (VIT), asthma, or thyroiditis (AITD, THY or TH).

In some embodiments, the patient is a pediatric patient, whereas in others the patient is an adult patient. In some embodiments, the genetic alteration is a single nucleotide variant (SNV). The genetic alteration may also be an insertion, deletion, translocation, or copy number variation (CNV), for example.

In some embodiments, the method comprises determining whether a genetic alteration is present in one or more of IL23R, LPHN2, PTPN22, TNM3, ANKRD30A, INS, NOD2, DAG1, SMAD3, ATG16L1, ZNF365, PTGER4, NKX2-3, ANKRD55, IL12B, LRRK2, IL5, SUOX, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, and PSMG1. In some embodiments, the method comprises determining whether a genetic alteration is present in at least 5, such as at least 10, such as at least 15, such as at least 20, or each of IL23R, LPHN2, PTPN22, TNM3, ANKRD30A, INS, NOD2, DAG1, SMAD3, ATG16L1, ZNF365, PTGER4, NKX2-3, ANKRD55, IL12B, LRRK2, IL5, SUOX, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, and PSMG1. In some embodiments, the method comprises determining whether a genetic alteration is present in one or more of LPHN2, TNM3, ANKRD30A, ADCY7, and CD40LG.

In some embodiments, the method comprises determining whether a genetic alteration is present in one or more of IL23R, TNM3, LRRK2, SBK1, IL2RA, ZMIZ1, IL21, and CARD9, wherein a genetic alteration in one or more of IL23R, TNM3, LRRK2, SBK1, IL2RA, ZMIZ1, IL21, and CARD9 indicates that the patient suffers from AS. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of CRB1, GPR35, CYTL3, IL12B, 8q24.23, JAK2, FNBP1, and SMAD3 is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or more of IL23R, PTPN22, TNM3, DAG1, ATG16L1, SUOX, SBK1, ADCY7, IL2RA, and ZMIZ1 is present, wherein a genetic alteration in one or more of IL23R, PTPN22, TNM3, DAG1, ATG16L1, SUOX, SBK1, ADCY7, IL2RA, and ZMIZ1 indicates that the patient suffers from PS. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of IL10, TSSC1, IL5, IL2RA, ADCY7, FUT2, and TNFRSF6B is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or more of TNM3, DAG1, SBK1, IL2RA, C40LG, ZMIZ1, and IL21 is present, wherein a genetic alteration in one or more of TNM3, DAG1, SBK1, IL2RA, C40LG, ZMIZ1, and IL21 indicates that the patient suffers from CEL. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of IL18R1, CYTL1, ERAP2, IL5, IL12B, 8q24.23, IKZF3, CD40LG, and RBMX is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or both of PTPN22 and TNM3 is present, wherein a genetic alteration in one or both of PTPN22 and TNM3 indicates that the patient suffers from SLE. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of IL10, TSSC1, GPR35, JAK2, ZNF365, TYK2, and TNFRSF6B is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or more of LPHN2, TNM3, and IL21 is present, wherein a genetic alteration in one or more of LPHN2, TNM3, and IL21 indicates that the patient suffers from CVID. In some such embodiments, the method further comprises determining whether a genetic alteration in one or both of EFNB2 and IKZF3 is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or more of IL23R, LPHN2, DAG1, PTGER4, SBK1, TNFSF15, CD40LG, IL21, CARD9, and PSMG1 is present, wherein a genetic alteration in one or more of IL23R, LPHN2, DAG1, PTGER4, SBK1, TNFSF15, CD40LG, IL21, CARD9, and PSMG1 indicates that the patient suffers from UC. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of IL10, TSSC1, IL18R1, GPR35, CYTL1, IL12B, JAK2, NKX2, SMAD3, ATXN2L, IKZF3, and TNFRSF6B is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or more of PTPN22, INS, SUOX, IL2RA, and IL21 is present, wherein a genetic alteration in one or more of PTPN22, INS, SUOX, IL2RA, and IL21 indicates that the patient suffers from T1D. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of CYTL1, 8q24.23, TYK2, and FUT2 is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or more of LPHN2, PTPN22, TNM3, ANKRD30A, ANKRD55, IL2RA, CD40LG, and IL21 is present, wherein a genetic alteration in one or more of LPHN2, PTPN22, TNM3, ANKRD30A, ANKRD55, IL2RA, CD40LG, and IL21 indicates that the patient suffers from JIA. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of CYTL1, ERAP2, 8q24.23, LURAP1L, FNBP1, EFNB2, IKZF3, TYK2, and RBMX is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or more of IL23R, PTPN22, DAG1, ATG16L1, PTGER4, ANKRD55, LRRK2, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, and PSMG1 is present, wherein a genetic alteration in one or more of IL23R, PTPN22, DAG1, ATG16L1, PTGER4, ANKRD55, LRRK2, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, and PSMG1 indicates that the patient suffers from CD. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of CRB1, IL10, TSSC1, IL18R1, CYTL1, ERAP2, IL5, IL12B, 8q24.23, JAK2, FNBP1, ZNF365, NKX2, SMAD3, ATXN2L, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, and RBMX is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or both of IL2RA and IL21 is present, wherein a genetic alteration in one or both of IL2RA and IL21 indicates that the patient suffers from AA. In some embodiments, the method comprises determining whether a genetic alteration in one or more of PTGER4, ANKRD55, IL2RA, CD40LG, and ZMIZ1 is present, wherein a genetic alteration in one or more of PTGER4, ANKRD55, IL2RA, CD40LG, and ZMIZ1 indicates that the patient suffers from MS. In some embodiments, the method comprises determining whether a genetic alteration in one or both of IL2A or IL21 is present, wherein a genetic alteration in one or both of IL2A or IL21 indicates that the patient suffers from PSC. In some embodiments, the method comprises determining whether a genetic alteration in one or more of PTPN22, ANKRD55, IL2RA, and IL21 is present, wherein a genetic alteration in one or more of PTPN22, ANKRD55, IL2RA, and IL21 indicates that the patient suffers from RA.

In some embodiments, the method comprises determining whether a genetic alteration in one or more of PTPN22 and IL2RA is present, wherein a genetic alteration in one or both of PTPN22 and IL2RA indicates that the patient suffers from VIT. In some embodiments, the method comprises determining whether a genetic alteration in one or more of PTPN22, TNM3, SBK1, IL2RA, and IL21 is present, wherein a genetic alteration in one or both of PTPN22, TNM3, SBK1, IL2RA, and IL21 indicates that the patient suffers from THY. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of IL18R1, CYTL1, FNBP1, IKZF3, TYK2, and TNFRSF6B is present.

In any of the above embodiments, the method may further comprise providing a report comprising suggested treatment(s) for the AID based upon the genetic alteration(s) identified in the method. In any of the above embodiments, the method may further comprise administering an effective amount of a treatment to the diagnosed patient after determination of genetic alterations in the patient, such as treatment with a molecule targeting a protein within the interaction network of the gene(s) harboring the genetic alteration(s). In such embodiments, the diagnosed patient may, for example, be prescribed an effective amount of one or more pharmaceutical agents listed in Tables 11 and 12. For instance, these tables list drugs associated with particular genes or gene pathways and the genetic alterations herein may reveal defects in one or more of those pathways that can be treated by a drug targeting that pathway and counteracting the effect of the genetic alteration in the patient.

In any of the above embodiments, genetic alterations may be found in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX at the corresponding chromosomal region and single nucleotide polymorphism (SNP) positions listed herein, for instance, in Tables 2a, 2b, 2c, or 2e.

These same general method steps and above optional embodiments may also be employed to determine whether a subject that does not currently have a particular AID is susceptible to developing one or more autoimmune disorders (AID) in the future. The same general method steps can, as another alternative, be applied to determining genetic alterations in a patient who has already been diagnosed with one or more AID, either to determine if the patient is susceptible to developing yet another AID or to determine possible treatments for the patient based on their particular set of genetic alterations. As above, such methods would comprise a) obtaining a biological sample from the subject; b) assaying nucleic acid from the sample to determine whether a genetic alteration in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX is present in the nucleic acid, wherein a genetic alteration in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX is correlated with presence of one or more AID in a subject; and c) determining that the subject is susceptible to developing one or more AID if a genetic alteration is present in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX. The same optional ways of conducting this method would also apply here as in the method of diagnosing a patient.

Namely, in some embodiments, the method for assessing altered susceptibility comprises determining whether a genetic alteration is present in at least 5, such as at least 10, such as at least 15, such as at least 20, such as at least 25, such as at least 30, such as at least 35, such as at least 40, or in each of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, § EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX. In some embodiments, the AID is one or more of ankylosing spondylitis (AS), psoriasis (PS or PSOR), celiac disease (CEL), systemic lupus erythematosus (SLE), common variable immunodeficiency (CVID), inflammatory bowel disease (IBD) ulcerative colitis (UC), type I diabetes (T1D), juvenile idiopathic arthritis (JIA), Crohn's disease (CD), alopecia areata (AA), multiple sclerosis (MS), primary biliary cirrhosis (PBC), primary sclerosing cholangitis (PSC), rheumatoid arthritis (RA), Sjogren's syndrome (SJO), systemic sclerosis (SSC), spondyoarthropathy (SPA), vitiligo (VIT), asthma, or thyroiditis (AITD, THY or TH).

In some embodiments, the patient is a pediatric patient, whereas in others the patient is an adult patient. In some embodiments, the genetic alteration is a single nucleotide variant (SNV). The genetic alteration may also be an insertion, deletion, translocation, or copy number variation (CNV), for example.

In some embodiments, the method for detecting altered susceptibility comprises determining whether a genetic alteration is present in one or more of IL23R, LPHN2, PTPN22, TNM3, ANKRD30A, INS, NOD2, DAG1, SMAD3, ATG16L1, ZNF365, PTGER4, NKX2-3, ANKRD55, IL12B, LRRK2, IL5, SUOX, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, and PSMG1. In some embodiments, the method comprises determining whether a genetic alteration is present in at least 5, such as at least 10, such as at least 15, such as at least 20, or each of IL23R, LPHN2, PTPN22, TNM3, ANKRD30A, INS, NOD2, DAG1, SMAD3, ATG16L1, ZNF365, PTGER4, NKX2-3, ANKRD55, IL12B, LRRK2, IL5, SUOX, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, and PSMG1. In some embodiments, the method comprises determining whether a genetic alteration is present in one or more of LPHN2, TNM3, ANKRD30A, ADCY7, and CD40LG.

In some embodiments, the method for detecting altered susceptibility comprises determining whether a genetic alteration is present in one or more of IL23R, TNM3, LRRK2, SBK1, IL2RA, ZMIZ1, IL21, and CARD9, wherein a genetic alteration in one or more of IL23R, TNM3, LRRK2, SBK1, IL2RA, ZMIZ1, IL21, and CARD9 indicates that the patient suffers from AS. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of CRB1, GPR35, CYTL3, IL12B, 8q24.23, JAK2, FNBP1, and SMAD3 is present.

In some embodiments, the method for detecting altered susceptibility comprises determining whether a genetic alteration in one or more of IL23R, PTPN22, TNM3, DAG1, ATG16L1, SUOX, SBK1, ADCY7, IL2RA, and ZMIZ1 is present, wherein a genetic alteration in one or more of IL23R, PTPN22, TNM3, DAG1, ATG16L1, SUOX, SBK1, ADCY7, IL2RA, and ZMIZ1 indicates that the patient suffers from PS. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of IL10, TSSC1, IL5, IL2RA, ADCY7, FUT2, and TNFRSF6B is present.

In some embodiments, the method for detecting altered susceptibility comprises determining whether a genetic alteration in one or more of TNM3, DAG1, SBK1, IL2RA, C40LG, ZMIZ1, and IL21 is present, wherein a genetic alteration in one or more of TNM3, DAG1, SBK1, IL2RA, C40LG, ZMIZ1, and IL21 indicates that the patient suffers from CEL. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of IL18R1, CYTL1, ERAP2, IL5, IL12B, 8q24.23, IKZF3, CD40LG, and RBMX is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or both of PTPN22 and TNM3 is present, wherein a genetic alteration in one or both of PTPN22 and TNM3 indicates that the patient is at altered risk for SLE. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of IL10, TSSC1, GPR35, JAK2, ZNF365, TYK2, and TNFRSF6B is present.

In some embodiments, the method comprises determining whether a genetic alteration in one or more of LPHN2, TNM3, and IL21 is present, wherein a genetic alteration in one or more of LPHN2, TNM3, and IL21 indicates that the patient is at altered risk for CVID. In some such embodiments, the method further comprises determining whether a genetic alteration in one or both of EFNB2 and IKZF3 is present.

In some embodiments, the method for detecting altered susceptibility comprises determining whether a genetic alteration in one or more of IL23R, LPHN2, DAG1, PTGER4, SBK1, TNFSF15, CD40LG, IL21, CARD9, and PSMG1 is present, wherein a genetic alteration in one or more of IL23R, LPHN2, DAG1, PTGER4, SBK1, TNFSF15, CD40LG, IL21, CARD9, and PSMG1 indicates that the patient is at altered risk for UC. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of IL10, TSSC1, IL18R1, GPR35, CYTL1, IL12B, JAK2, NKX2, SMAD3, ATXN2L, IKZF3, and TNFRSF6B is present.

In some embodiments, the method for detecting altered susceptibility comprises determining whether a genetic alteration in one or more of PTPN22, INS, SUOX, IL2RA, and IL21 is present, wherein a genetic alteration in one or more of PTPN22, INS, SUOX, IL2RA, and IL21 indicates that the patient suffers from T1D. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of CYTL1, 8q24.23, TYK2, and FUT2 is present.

In some embodiments, the method for detecting altered susceptibility comprises determining whether a genetic alteration in one or more of LPHN2, PTPN22, TNM3, ANKRD30A, ANKRD55, IL2RA, CD40LG, and IL21 is present, wherein a genetic alteration in one or more of LPHN2, PTPN22, TNM3, ANKRD30A, ANKRD55, IL2RA, CD40LG, and IL21 indicates that the patient is at altered risk for JIA. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of CYTL1, ERAP2, 8q24.23, LURAP1L, FNBP1, EFNB2, IKZF3, TYK2, and RBMX is present.

In some embodiments, the method for detecting altered susceptibility comprises determining whether a genetic alteration in one or more of IL23R, PTPN22, DAG1, ATG16L1, PTGER4, ANKRD55, LRRK2, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, and PSMG1 is present, wherein a genetic alteration in one or more of IL23R, PTPN22, DAG1, ATG16L1, PTGER4, ANKRD55, LRRK2, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, and PSMG1 indicates that the patient is at altered risk for CD. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of CRB1, IL10, TSSC1, IL18R1, CYTL1, ERAP2, IL5, IL12B, 8q24.23, JAK2, FNBP1, ZNF365, NKX2, SMAD3, ATXN2L, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, and RBMX is present.

In some embodiments, the method for detecting altered susceptibility comprises determining whether a genetic alteration in one or both of IL2RA and IL21 is present, wherein a genetic alteration in one or both of IL2RA and IL21 indicates that the patient suffers from AA. In some embodiments, the method comprises determining whether a genetic alteration in one or more of PTGER4, ANKRD55, IL2RA, CD40LG, and ZMIZ1 is present, wherein a genetic alteration in one or more of PTGER4, ANKRD55, IL2RA, CD40LG, and ZMIZ1 indicates that the patient suffers from MS. In some embodiments, the method comprises determining whether a genetic alteration in one or both of IL2A or IL21 is present, wherein a genetic alteration in one or both of IL2A or IL21 indicates that the patient is at altered risk for PSC. In some embodiments, the method comprises determining whether a genetic alteration in one or more of PTPN22, ANKRD55, IL2RA, and IL21 is present, wherein a genetic alteration in one or more of PTPN22, ANKRD55, IL2RA, and IL21 indicates that the patient suffers from RA.

In some embodiments, the method for detecting altered susceptibility comprises determining whether a genetic alteration in one or more of PTPN22 and IL2RA is present, wherein a genetic alteration in one or both of PTPN22 and IL2RA indicates that the patient is at altered risk for VIT. In some embodiments, the method comprises determining whether a genetic alteration in one or more of PTPN22, TNM3, SBK1, IL2RA, and IL21 is present, wherein a genetic alteration in one or both of PTPN22, TNM3, SBK1, IL2RA, and IL21 indicates that the patient suffers from THY. In some such embodiments, the method further comprises determining whether a genetic alteration in one or more of IL18R1, CYTL1, FNBP1, IKZF3, TYK2, and TNFRSF6B is present.

In any of the above embodiments, the method may further comprise providing a report comprising suggested treatment(s) for the AID based upon the genetic alteration(s) identified in the method. In any of the above embodiments, the method may further comprise administering an effective amount of a treatment to the diagnosed patient after determination of genetic alterations in the patient, such as treatment with a molecule targeting a protein within the interaction network of the gene(s) harboring the genetic alteration(s). In such embodiments, the diagnosed patient may, for example, be prescribed an effective amount of one or more pharmaceutical agents listed in Tables 11 and 12. For instance, these tables list drugs associated with particular genes or gene pathways and the genetic alterations herein may reveal defects in one or more of those pathways that can be treated by a drug targeting that pathway and counteracting the effect of the genetic alteration in the patient.

In any of the above embodiments, genetic alterations may be found in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX at the corresponding chromosomal region and single nucleotide polymorphism (SNP) positions listed herein, for instance, in Tables 2a, 2b, 2c, or 2e.

Also included herein are methods of treating a patient with one or more AID, comprising determining whether a genetic alteration is present in the patient according to the methods of any the above methods, and administering an effective amount of one or more pharmaceutical agents listed in Tables 11 and 12 to the patient based upon identification of the genetic alteration(s) determined, i.e. matching a drug targeting a particular gene or network to a patient with a genetic alteration affecting that gene or network.

The present disclosure also includes systems for detecting a genetic alteration in a subject, comprising probes specific for and capable of determining single nucleotide variations (SNVs) in at least 5, such as at least 10, at least 15, at least 20, at least 25, at least 30, at least 35, at least 40, or each of the following genes: IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX. In some embodiments, the system is capable of determining copy number variations (CNVs) in in at least 5, such as at least 10, at least 15, at least 20, at least 25, at least 30, at least 35, at least 40, or each of: IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX. In some embodiments, the system is capable of determining SNVs in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, and RBMX are at the corresponding chromosomal region and SNP positions listed in Tables 2a, 2b, 2c, or 2e. In some embodiments, the probes are comprised on solid support matrix, such as a chip.

The present disclosure also includes methods for treating one or more autoimmune disorders (AID) in a patient, comprising: a) obtaining genotype sequence information from a biological sample obtained from a patient; b) detecting the presence of at least one genetic alteration in a chromosomal region and associated gene selected from:

-   rs2066363 1p31.1 LPHN2, wherein said pAID is selected from CVID and     JIA; -   rs7660520 4q35.1 TNM3, wherein said pAID is selected from THY, AS,     CEL, SLE, CVID and JIA; -   rs7100025 10p11.21 ANKRD30A, wherein said pAID is JIA; -   rs77150043 16q12.1 ADCY7, wherein said pAID is PS and CD; -   rs2807264 Xq26.3 CD40LG, wherein said pAID is CEL, UC and CD;     wherein detection of said one or more of said genetic alterations is     correlated with an altered risk for developing one or more AID     relative to control patients lacking said genetic alterations;     and c) treating the patient with an effective amount of one or more     pharmaceutical agents listed in Tables 11 and 12 targeting the     indicated pAID associated gene or its interaction network. Such a     method may further comprise detection of:

rs11580078 1p31.3 IL23R; rs6679677 1p13.2 PTPN22; rs36001488 2q37.1 ATG16L1; rs4625 3p21.31 DAG1; rs62324212 4q27 IL21; rs7725052 5p13.1 PTGER4; rs7731626 5q11.2 ANKRD55; rs11741255 5q31.1 IL5; rs755374 5q33.3 IL12B; rs4246905 9q32 TNFSF15; rs11145763 9q34.3 CARD9; rs706778 10p15.1 IL2RA; rs10822050 10q21.2 ZNF365; rs1250563 10q22.3 ZMIZ1; rs1332099 10q24.2 NKX2-3; rs17885785 11p15.5 INS; rs17466626 12q12 LRRK2; rs1689510 12q13.2 SUOX; rs72743477 15q22.33 SMAD3; rs12598357 16p11.2 SBK1; rs117372389 16q12.1 NOD2; and rs2836882 21q22.2 PSMG1.

In some embodiments, two or more agents are administered to the patient. In some embodiments, the disease is JIA and said drug target is ANKRD30A. In some embodiments, the step of detecting the presence of said genetic alteration further comprises the step of analyzing a polynucleotide sample to determine the presence of said genetic alteration by performing a process selected from the group consisting of detection of specific hybridization, measurement of allele size, restriction fragment length polymorphism analysis, allele-specific hybridization analysis, single base primer extension reaction, and sequencing of an amplified polynucleotide. In some embodiments, the genotype sequence information is obtained from DNA and in some it is obtained from RNA.

Another exemplary method for treating one or more AID, such as one or more pAID, in a patient comprises obtaining genotype sequence information from a biological sample obtained from a patient, detecting the presence of at least one AID associated single nucleotide polymorphism (SNP) in a chromosomal region and associated gene selected from rs2066363 on1p31.1 in LPHN2 wherein said AID is selected from CVID and JIA, rs7660520 on 4q35.1 in TNM3; wherein said AID is selected from THY, AS, CEL, SLE, CVID and JIA; rs7100025 on 10p11.21 in ANKRD30A wherein said AID is JIA, rs77150043 on 16q12.1 in ADCY7 wherein said AID is PS and CD, rs2807264 on Xq26.3 in CD40LG; wherein said AID is CEL, UC and CD wherein detection of said one or more SNP is correlated with an altered risk for developing one or more pAID relative to control patients lacking said SNP. The method may further entail treating patients having an altered propensity for AID with one or more pharmaceutical agents listed in Table 11 or Table 12, which are known to target the indicated AID associated gene(s), thereby reducing symptoms or inhibiting development of said one or more AID. The method can further comprise detection of rs11580078 on 1p31.3 in IL23R, rs6679677 on 1p13.2 in PTPN22, rs36001488 on 2q37.1 in ATG16L1, rs4625 on 3p21.31 in DAG1, rs62324212 on 4q27 in IL21, rs7725052 on 5p13.1 in PTGER4, rs7731626 on 5q11.2 in ANKRD55, rs11741255 on 5q31.1 in IL5, rs755374 on 5q33.3 in IL12B, rs4246905 on 9q32 in TNFSF15, rs11145763 on 9q34.3 in CARD9, rs706778 on 10p15.1 in IL2RA, rs10822050 on 10q21.2 in ZNF365, rs1250563 on 10q22.3 in ZMIZ1, rs1332099 on 10q24.2 in NKX2-3, rs17885785 on 11p15.5 in INS, rs17466626 on 12q12 in LRRK2, rs1689510 on 12q13.2 in SUOX, rs72743477 on 15q22.33 in SMAD3, rs12598357 on 16p11.2 in SBK1, rs117372389 on 16q12.1 in NOD2; and rs2836882 on 21q22.2 in PSMG1, and treating said patient with one or more pharmaceutical agents modulating the activity of the AID associated gene. SNP-containing nucleic acids listed in Table 1, Supplementary Table 1c, or Table 11 may also be detected and patients harboring such SNPs treated with the indicated agents. The SNP containing nucleic acids of the invention may be detected in a variety of different ways including, without limitation, detection via specific hybridization, measurement of allele size, restriction fragment length polymorphism analysis, allele-specific hybridization analysis, single base primer extension reaction, and sequencing of an amplified polynucleotide. In certain embodiments of the invention, the genotype information is provided on a solid support matrix, such as on a chip or otherwise in silico. In any such embodiments, the patient may be a pediatric or an adult patient.

In yet another aspect of the disclosure, a method for identifying agents that alter immune signaling and aberrant autoimmune cellular phenotypes is provided. An exemplary method comprises providing cells expressing at least one SNP containing nucleic acid associated with AID and set forth in Table 1, Supplementary Table 1c, and Table 11, providing cells which express the cognate wild type sequences corresponding to the SNP containing nucleic acid, contacting the cells above with a test agent and analyzing whether said agent alters immune signaling and or aberrant autoimmune phenotypes of cells of step a) relative to those of step b), thereby identifying agents which modulate autoimmune function of proteins encoded by AID associated SNP containing nucleic acids. For example, the present disclosure also comprises methods for identifying an agent that alters immune signaling and aberrant autoimmune phenotypes, comprising: a) providing cells expressing at least one nucleic acid comprising at least one genetic alteration as claimed in any one of the preceding claims; b) providing cells which express the cognate wild type sequences corresponding to the genetic alteration of a); c) contacting the cells of a) and b) with a test agent; and d) analyzing whether said agent alters immune signaling and or aberrant autoimmune phenotypes of cells of step a) relative to those of step b). Host cells, vectors and kits for practicing the methods disclosed herein are also within the scope of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1I. The ten pAID case cohorts and top pAID association loci identified. FIG. 1A: The ten pediatric autoimmune diseases studied. Autoimmune Thyroiditis (THY), Ankylosing Spondylitis (AS), Psoriasis (PS), Celiac Disease (CEL), Systemic Lupus Erythematosus (SLE), Type-1-Diabetes (T1D), Juvenile Idiopathic Arthritis (JIA), Common Variable Immunodeficiency (CVID), Ulcerative colitis (UC) and Crohn's Disease (CD). FIG. 1B: Top pAID association signals identified by performing an inverse chi-square meta-analysis. The top 27 loci (where at least one “lead” SNP reached GWS: P_(META)<5×10⁸) were annotated with the candidate gene name (HGNC ID). FIG. 1C: Novel and established pAID association loci: (Top Left) rs706778 (chr10p15.1) is a known DNAse I peak, an intronic SNP in IL2RA, and associated with THY, AS, PS, CEL, T1D, and JIA. (Top Right) rs755374 (chr5q33.3) is an intergenic SNP upstream of IL12B and associated with AS, CEL, UC and CD, (Bottom Left) rs2807264 (chrXq26.3) mapping near CD40LG is associated with CEL, UC, and CD, and chr15q22.33 (rs72743477), also mapping to an intronic position in SMAD3, is associated with UC, CD, and AS. (Bottom Right). SNPs are shaded based on their pairwise LD (r²) with respect to the most strongly associated “lead” SNP in the locus. Associated pAIDs are indicated at the upper left. FIG. 1D: “Pleiotropic” candidate genes have pleiotropic effect size and direction across pAIDs. While a few “pleiotropic” SNPs have consistent effect directions across diseases (IL21), for many loci (e.g. PTPN22 and CLEC16A), the candidate SNP may have variable effect directions across the diseases. The radii of the wedges correspond to the absolute value of the Z-scores (beta/se) for each pAID while the shading indicates whether the SNP is protective (grey-shaded) or risk-associated (unshaded) for each disease. FIG. 1E: Genetically-inferred ancestry estimates of included cohorts based on principal components analysis (PCA). PCA results from genome wide SNP genotypes using overlapping SNPs from the genotyped study cohort and from the HapMap 3 reference panel dataset (left, center) or from the former alone (right) along the top two principal components. FIG. 1F: Circle plot of results from the pooled chi-square meta-analysis across the genome. From outside to inside: Chromosome number; CNV hotspots on chromosome; significant trait/disease-associated SNPs (TASs), SNP Density with different shading to distinguish each chromosome; dbSNP SNP density; 1KGP; HapMap; OMIM gene distribution; Variants distribution (DGV); Variants annotated from the genetic associations database (GAD). See the Internet site: “jjwanglab” dot “org” back-slash “gwasrap” for the details of the annotation methods. FIG. 1G: Distribution of pAID associated SNPs by effect size and allele frequency. Distribution of the 27 or 46 GWS or GWM lead SNPs effect sizes based on how many diseases were identified as associated with each SNP based on the results of the model search (left). The top 46 GWM SNPs are grouped by the number of associated pAIDs and distributed by the magnitude of the expected effect size obtained from logistic regression analysis using the disease combination identified by the subtype model search. FIG. 1H: Transcript Consequences for the 27 GWS lead SNPs reported by Ensemble Variant Effect Predictor. For each locus, only the top SNP reaching the most significant P-value was used to avoid redundancy in percentage calculations. FIG. 1I: Distribution and enrichment of experimental and predicted annotations for the top 27 GWS SNPs. Number of SNPs (or LD proxies) out of the 27 SNPs for which annotations were curated, along with the enrichment P-values based on permutation testing of simulated SNP-sets drawn from the 1KGP-RP. The annotation frequencies were used to calculate the relative enrichment of pAID SNPs as compared to 10,000 random 100 SNP-sets drawn from the genome in each annotation category as shown by the histogram.

FIGS. 2A, 2B, 2C-1, and 2C-2. Pleiotropic loci with heterogeneous effect directions across pAIDs. FIG. 2A: Disease-specific Z-scores (beta/SE) for each SNP identified as having opposite effect directions across the ten pAIDs and as detailed in (FIG. 2A). Graphical markers (with different shapes for each disease) denote diseases where the indicated SNP has an opposite effect as compared to the group of pAID identified based as sharing the lead association based on results of the model search (Black Diamond). FIG. 2B: Clustering of pAIDs across the lead loci based on disease-specific effect sizes. Agglomerative hierarchical clustering across ten pAIDs based on normalized directional z-scores (beta/standard error) resulting from logistic regression analysis in each disease for the 27 lead loci based on those disease combinations identified by the model search analysis as that which produced the strongest association test statistic. FIGS. 2C-1 and 2C-2: QQ plots of summary-level results obtained from the ten disease-specific case-control pAID GWAS using the shared controls either with or without the SNPs across the extended MHC (FIG. 2C-1) or the pooled inverse chi-square meta-analysis. Extended MHC SNPs were included in these FIG. 2C-1 and excluded in FIG. 2C-2.

FIGS. 3A-3E. Integrated annotation of pAID association loci using existing predictive and experimental datasets. FIG. 3A: Biological, functional and literature annotations for the 27 loci reaching GWS on meta-analysis. Loci (identified by the lead SNPs and candidate gene names) are organized by column, where the shaded rug denotes the associated pAIDs, the functional annotations are found at the top of the table and the shaded bar at the bottom illustrates meta-analysis P_(meta)-value. For each locus, the lead SNP and proxy SNPs (r²>0.8) are included in the annotation protocol; see Methods for details. Abbreviations: cpg: CpG islands; dgv: copy number variable regions; dnase: DNAse hypersensitivity I sites; eqtl: expression quantitative trail loci; gad: known genetic associations; gerp: conserved positions; mir: miRNAs; sift: functional mutations in SIFT; tfbs: transcription factor binding sites. FIG. 3B: Distribution and enrichment of experimental and predicted annotations for the top 27 GWS SNPs. The annotation frequencies were used to calculate the relative enrichment of pAID SNPs (black bar) as compared to 10,000 random 100 SNP-sets drawn from the genome in each annotation category as shown by the histogram. FIGS. 3C and 3D: Disease-specific GWAS results across the extended MHC for T1D and JIA. Summary-level association results from the disease-specific, case-control GWAS showing that the top signals obtained across markers mapping to the extended MHC analysis as observed for T1D (a) and JIA (b). The shaded scale is based on the p-values (most significant: dark grey at top to least significant: white). FIG. 3E: Association of Top MHC region signal from each pAID with the other pAIDs. P-values from each of the ten pAIDs are tabulated at the 10 SNPs that were identified as being the lead signals for each respective pAID (as annotated in the first column).

FIGS. 4A-4D. Tissue-Specific Gene Set Enrichment Analysis (TGSEA) identifies autoimmune-associated gene expression patterns across immune cells and tissues using pediatric and adult autoimmune datasets. FIG. 4A: Expression enrichment of autoimmune-associated genes across human tissues. Distribution of TGSEA enrichment scores (ES) values across 126 tissues for pAID-associated genes (Center) either with (Circles) or without (Triangles) the extended MHC (for clarity, also labeled in the plot with a (+) or (−), respectively). Results for the pAID gene set is compared to those obtained for known genes associated with Crohn's Disease (Left) and Schizophrenia (Right). Tissues/cell types are classified as immune or non-immune and ranked left to right in each panel based on the magnitude of the ES test statistic. FIG. 4B: Enrichment of pAID-associated gene expression across diverse murine immune cell types. Distribution of pAID-associated gene ES values across murine immune cell types either including (darker shaded peak located between 5 and 10) or excluding the genes within the MHC (lighter shaded peak located between about 4 and 6); results compared to genes associated with Crohn's Disease ‘CD’ (flatter peak between about 4 and 12), Schizophrenia ‘Schizo’ (light shaded sharp, high peak at about 2-3), LDL cholesterol ‘LDL’ (medium shaded sharp, high peak between 0 and 2), or Body Mass Index ‘BMI’ (smaller peak overlapping with the Schizo and LDL peaks located at about 2-3) abstracted from the NHGRI GWAS Catalog. FIG. 4C: Hierarchical clustering of based on expression of “pleiotropic” candidate gene associated with three or more autoimmune diseases across the murine immune cells. Boxes denote gene clusters enriched for specific disease associations discussed in the text. FIG. 4D: Functional, regulatory, conserved and literature-reported annotations for the 46 GWM or GWS lead SNPs reaching P_(META)<1×10⁻⁶. For each SNP, the shading of the associated pAIDs and the shaded bar at the bottom illustrates the strength of the association with the specific disease combination (P_(META)-value). The right side of the figure corresponds to the pAIDs identified as being associated with each lead SNP based on model search. Abbreviations: cpg: CPG islands; dgv: copy number variable regions; dnase: DNAse hypersensitivity I sites; eqtl: expression quantitative trail loci; gad: known genetic associations; gerp: conserved positions; mir: miRNAs; sift: functional mutations in SIFT; tfbs: transcription factor binding sites.

FIGS. 5A-5E: Genetic variants shared across the ten pAIDs reveal autoimmune disease networks. FIG. 5A: Quantification of pAID genetic sharing by genome-wide pairwise sharing test including SNPs within the extended MHC. Correlation plot of the pairwise pAID GPS test; the shading intensity and the size of the circle are proportional to the strength of the correlation as the negative base ten logarithms of the GPS test P-values.

FIG. 5B: Quantification of autoimmune disease genetic sharing by locus-specific pairwise sharing. Undirected weighted network (UWN) graph depicting results from the LPS test. Edge size represents the magnitude of the LPS test statistic; labeled nodes for each of the 17 autoimmune diseases are positioned based on a force-directed layout. Edges shown represent significant pairs after Bonferroni adjustment (P_(adj)<0.05). FIG. 5C: Protein-Protein Interaction network analysis of the top pAID associated protein candidates in STRING; Action view of protein interactions observed across the top 46 GWM (P<1×10⁻⁶) signals, of which 44 were mappable to corresponding proteins. Views are generated based on results for known and predicted protein interaction produced by STRING DB Homo sapiens database. The plots shown are results of the “action” view where the molecular actions (stimulatory, repressive or binding) are illustrated by the arrows. FIG. 5D: pAID associated genes are enriched in human immune tissues (KS test). Distribution of TGSEA enrichment scores (ES) values across 126 tissues derived from 1-sided Kolmogorov-Smirnov (KS) test statistic for pAID-associated genes (Center) with (Circles) and without (Triangles) the extended MHC ‘extended MHC’. Known Crohn's Disease (Left) and Schizophrenia (Right) genes from the NHGRI GWAS Catalog are included as reference profiles. Tissues/cell types are classified as immune or non-immune and ranked left to right in each panel based on the magnitude of the KS test statistic. FIG. 5E: Differential enrichment of pAID-associated gene transcripts across immune cells based on cell lineage and developmental stage. Distribution of ES values for pAID-associated genes or adult/general autoimmune disease associated genes (compared to the remaining transcripts in the dataset) examined across all ImmGen cell types when classified by cell lineage and developmental stage, either including (Left) or excluding the extended MHC region (Right). Genes from adult cohorts were obtained from previously report association genes as noted in the Immunochip consortium database (available: immunobase “dot” org).

FIGS. 6A-6C. FIG. 6A: Protein-Protein Interaction network analysis in STRING. Evidence view of protein interactions observed for the (left) 27 (P<1×10⁻⁸) GWS loci, (center) 46 GWM (P<1×10⁻⁶) signals and (right) the interacting proteins in the JAK2 signaling cascade identified by the pAID meta-analysis using the PPI analysis module in webgestalt. Views are generated based on results for known and predicted protein-protein interactions identified using the STRING DB homo sapiens database. Plots show results of the “evidence” view such that each line demonstrates one source of PPI data. FIG. 6B: Protein-Protein Interaction network analysis in DAPPLE. Interactions identified using the protein network interaction tool Dapple. The input seeds are the 46 candidate GWM loci (inclusive of 200 kilobases up- and downstream of the lead SNPs). Seed scores Pdapple were used to color the protein nodes in the network plot. FIG. 6C: Biological pathways enriched for pAID-associated genes. Most significantly enriched pathways are identified. Input gene list from the GBAT was used to identify candidate biological pathways or biological processes important in pAIDs; pathways were manually annotated such that corresponding pathways that were named slightly differently across the respective databases could be directly compared and meta-analyzed. Each data point represents a test statistic (P- or q-value) obtained from DAVID (FDR, white circles), IPA (BH, black squares) or GSEA (BH, black circles) with annotation databases for a given “shared” pathway (ranked by their overall Fisher meta-analysis P-values on the x-axis). The area plot is bound by the Fisher's meta-analysis−log 10 (P-value) on the y-axis. The common pathways (found in all 3 databases) are annotated at top.

FIGS. 7A-7C. FIG. 7A: Top nine lead SNPs at which the direction of effect (DoE) observed across one or more pAIDs oppose that for the disease combination identified by model search. Abbreviations: SNP: rsID dbSNP 138; GENE: Candidate Gene Name (HGNC); REGION: Cytogenetic band; A1: alternative allele used in the logistic regression; pAIDs model: pAID(s) associated with this SNP based on the model search; BETA (SE) model: effect size and standard error of the SNP based on logistic regression combining cases from the diseases identified on the model search; pAID: the disease showing the opposite effect direction than that of the group of diseases identified by the subtype search; BETA (SE): z-score or effect size and standard error of the SNP for the disease found to have an opposite effect direction; P-value: disease-specific GWAS P-value. FIG. 7B: Quantification of pAID genetic sharing by genome-wide pairwise sharing test including (top) or excluding (bottom) the SNPs within the extended MHC. Correlation plot of the pairwise pAID GPS test; the shading intensity and the size of the circle are proportional to the strength of the correlation as the negative base ten logarithms of the GPS test P-values. FIG. 7C: Undirected weighted network (UWN) graph depicting results from the LPS test. Edge size represents the magnitude of the LPS test statistic; labeled nodes for each of the 17 autoimmune diseases are positioned based on a force-directed layout (Methods). Edges illustrating pairwise relationships reaching at least nominal significance based on the LPS test (P<0.05) are shown.

As noted earlier, color versions of certain figures included herein have also been published in Y. R. Li et al, Nature Medicine Aug. 24, 2015, online publication doi: 10.1038 “backslash” nm.3933, and in the supplemental materials for that publication, and those figures are incorporated by reference herein.

DETAILED DESCRIPTION OF THE INVENTION

Genome wide association studies (GWAS) have identified multiple susceptibility genes, including shared associations across clinically-distinct disease groups and autoimmune diseases. The present inventors performed an inverse chi-square meta-analysis across ten pediatric age-of-onset autoimmune diseases (pAIDs) in a case-control study including over 6,035 cases and 10,718 shared population-based controls. Twenty-seven genome-wide significant loci associated with one or more pAIDs were identified, mapping to in silico-replicated autoimmune-associated genes (including IL2RA) and novel, candidate loci with established immunoregulatory functions including LPHN2, TNM3, ANKRD30A, ADCY7, and CD40LG. The pAID-associated SNPs are functionally-enriched for DNAse-hypersensitivity sites, expression quantitative trait loci, micro-RNA binding sites and coding variants. Biologically-correlated, pAID-associated candidate gene-sets were also identified based on immune cell expression profiling, and show evidence of genetic sharing. Network and protein-interaction analyses demonstrated converging roles for the T helper type 1 (T_(H)1)/T_(H)2/T_(H)17, JAK-STAT, interferon and interleukin signaling pathways in multiple autoimmune diseases.

Definitions

For purposes of the present invention, “a” or “an” entity refers to one or more of that entity; for example, “a cDNA” refers to one or more cDNA or at least one cDNA. As such, the terms “a” or “an,” “one or more” and “at least one” can be used interchangeably herein. It is also noted that the terms “comprising,” “including,” and “having” can be used interchangeably. Furthermore, a compound “selected from the group consisting of” refers to one or more of the compounds in the list that follows, including mixtures (i.e. combinations) of two or more of the compounds. According to the present invention, an isolated, or biologically pure molecule is a compound that has been removed from its natural milieu. As such, “isolated” and “biologically pure” do not necessarily reflect the extent to which the compound has been purified. An isolated compound of the present invention can be obtained from its natural source, can be produced using laboratory synthetic techniques or can be produced by any such chemical synthetic route.

An “Auto Immune Disease” is abbreviated AID herein and includes but is not limited to one or more of ankylosing spondylitis (AS), psoriasis (PS or PSOR), celiac disease (CEL), systemic lupus erythematosus (SLE), common variable immunodeficiency (CVID), inflammatory bowel disease (IBD) ulcerative colitis (UC), type I diabetes (T1D), juvenile idiopathic arthritis (JIA), Crohn's disease (CD), alopecia areata (AA), multiple sclerosis (MS), primary biliary cirrhosis (PBC), primary sclerosing cholangitis (PSC), rheumatoid arthritis (RA), Sjogren's syndrome (SJO), systemic sclerosis (SSC), spondyoarthropathy (SPA), vitiligo (VIT), asthma, or thyroiditis (AITD, THY or TH). A “Pediatric Auto Immune Disease” is abbreviated pAID herein and includes but is not limited to each of the above diseases in a “pediatric” subject, which is defined herein as a subject under the age of 18. In contrast, an “adult” subject is 18 or older.

A “single nucleotide variation (SNV),” also interchangeably referred to as a “single nucleotide polymorphism (SNP)” herein, refers to a change in which a single base in the DNA differs from the usual base at that position. These single base changes are often called SNPs or “snips.” Millions of SNP's have been cataloged in the human genome. Some SNPs such as that which causes sickle cell are responsible for disease. Other SNPs are normal variations in the genome.

“AID-associated SNP or AID-associated specific marker” or “AID-associated marker” is a SNP or marker that is associated with an increased risk of developing an AID and that is found at a lower frequency or is not generally found in normal subjects who do not have the AID. Such markers may include but are not limited to nucleic acids, proteins encoded thereby, or other small molecules. In some cases, the SNP or marker is an AID-associated SNP or AID-associated marker.

The term “genetic alteration” as used herein refers to a change from the wild-type or reference sequence of one or more nucleic acid molecules. Genetic alterations include without limitation, base pair substitutions, additions and deletions of at least one nucleotide from a nucleic acid molecule of known sequence. The term “genetic alteration” may also be applied to a protein and encompasses without limitation amino acid substitutions, insertions, and deletions. An “allelic variation” refers to the presence of an allele that differs from a wild-type or reference allele, i.e. one allele that has a genetic alteration in comparison to a wild-type or reference allele.

“Linkage” describes the tendency of genes, alleles, loci or genetic markers to be inherited together as a result of their location on the same chromosome, and is measured by percent recombination (also called recombination fraction, or θ) between the two genes, alleles, loci or genetic markers. The closer two loci physically are on the chromosome, the lower the recombination fraction will be. Normally, when a polymorphic site from within a disease-causing gene is tested for linkage with the disease, the recombination fraction will be zero, indicating that the disease and the disease-causing gene are always co-inherited. In rare cases, when a gene spans a very large segment of the genome, it may be possible to observe recombination between polymorphic sites on one end of the gene and causative mutations on the other. However, if the causative mutation is the polymorphism being tested for linkage with the disease, no recombination will be observed.

“Centimorgan” is a unit of genetic distance signifying linkage between two genetic markers, alleles, genes or loci, corresponding to a probability of recombination between the two markers or loci of 1% for any meiotic event.

“Linkage disequilibrium” or “allelic association” means the preferential association of a particular allele, locus, gene or genetic marker with a specific allele, locus, gene or genetic marker at a nearby chromosomal location more frequently than expected by chance for any particular allele frequency in the population.

The term “solid matrix” or “solid support matrix” as used herein refers to any format, such as beads, microparticles, a microarray, the surface of a microtitration well or a test tube, a dipstick or a filter. The material of the matrix may be polystyrene, cellulose, latex, nitrocellulose, nylon, polyacrylamide, dextran or agarose. In some embodiments, the matrix may be in the form of a chip.

The phrase “consisting essentially of” when referring to a particular nucleotide or amino acid means a sequence having the properties of a given SEQ ID NO:. For example, when used in reference to an amino acid sequence, the phrase includes the sequence per se and molecular modifications that would not affect the functional and novel characteristics of the sequence.

“Target nucleic acid” as used herein refers to a previously defined region of a nucleic acid present in a complex nucleic acid mixture wherein the defined wild-type region contains at least one known nucleotide variation that may or may not be associated with pAID. The nucleic acid molecule may be isolated from a natural source by cDNA cloning or subtractive hybridization or synthesized manually. The nucleic acid molecule may be synthesized manually by the triester synthetic method or by using an automated DNA synthesizer.

With regard to nucleic acids used in the invention, the term “isolated nucleic acid” is sometimes employed. This term, when applied to DNA, refers to a DNA molecule that is separated from sequences with which it is immediately contiguous (in the 5′ and 3′ directions) in the naturally occurring genome of the organism from which it was derived. For example, the “isolated nucleic acid” may comprise a DNA molecule inserted into a vector, such as a plasmid or virus vector, or integrated into the genomic DNA of a prokaryote or eukaryote. An “isolated nucleic acid molecule” may also comprise a cDNA molecule. An isolated nucleic acid molecule inserted into a vector is also sometimes referred to herein as a recombinant nucleic acid molecule.

With respect to RNA molecules, the term “isolated nucleic acid” primarily refers to an RNA molecule encoded by an isolated DNA molecule as defined above. Alternatively, the term may refer to an RNA molecule that has been sufficiently separated from RNA molecules with which it would be associated in its natural state (i.e., in cells or tissues), such that it exists in a “substantially pure” form.

By the use of the term “enriched” in reference to nucleic acid it is meant that the specific DNA or RNA sequence constitutes a significantly higher fraction (2-5 fold) of the total DNA or RNA present in the cells or solution of interest than in normal cells or in the cells from which the sequence was taken. This could be caused by a person by preferential reduction in the amount of other DNA or RNA present, or by a preferential increase in the amount of the specific DNA or RNA sequence, or by a combination of the two. However, it should be noted that “enriched” does not imply that there are no other DNA or RNA sequences present, just that the relative amount of the sequence of interest has been significantly increased.

It is also advantageous for some purposes that a nucleotide sequence is in purified form. The term “purified” in reference to nucleic acid does not require absolute purity (such as a homogeneous preparation); instead, it represents an indication that the sequence is relatively purer than in the natural environment (compared to the natural level, this level should be at least 2-5 fold greater, e.g., in terms of mg/ml). Individual clones isolated from a cDNA library may be purified to electrophoretic homogeneity. The claimed DNA molecules obtained from these clones can be obtained directly from total DNA or from total RNA. The cDNA clones are not naturally occurring, but rather are preferably obtained via manipulation of a partially purified naturally occurring substance (messenger RNA). The construction of a cDNA library from mRNA involves the creation of a synthetic substance (cDNA) and pure individual cDNA clones can be isolated from the synthetic library by clonal selection of the cells carrying the cDNA library. Thus, the process includes the construction of a cDNA library from mRNA and isolation of distinct cDNA clones and yields an approximately 10⁶ fold purification of the native message. Thus, purification of at least one order of magnitude, preferably two or three orders, and more preferably four or five orders of magnitude is expressly contemplated. Thus the term “substantially pure” refers to a preparation comprising at least 50-60% by weight the compound of interest (e.g., nucleic acid, oligonucleotide, etc.). More preferably, the preparation comprises at least 75% by weight, and most preferably 90-99% by weight, the compound of interest. Purity is measured by methods appropriate for the compound of interest.

The term “complementary” describes two nucleotides that can form multiple favorable interactions with one another. For example, adenine is complementary to thymine as they can form two hydrogen bonds. Similarly, guanine and cytosine are complementary since they can form three hydrogen bonds. Thus if a nucleic acid sequence contains the following sequence of bases, thymine, adenine, guanine and cytosine, a “complement” of this nucleic acid molecule would be a molecule containing adenine in the place of thymine, thymine in the place of adenine, cytosine in the place of guanine, and guanine in the place of cytosine. Because the complement can contain a nucleic acid sequence that forms optimal interactions with the parent nucleic acid molecule, such a complement can bind with high affinity to its parent molecule.

With respect to single stranded nucleic acids, particularly oligonucleotides, the term “specifically hybridizing” refers to the association between two single-stranded nucleotide molecules of sufficiently complementary sequence to permit such hybridization under pre-determined conditions generally used in the art (sometimes termed “substantially complementary”). In particular, the term refers to hybridization of an oligonucleotide with a substantially complementary sequence contained within a single-stranded DNA or RNA molecule of the invention, to the substantial exclusion of hybridization of the oligonucleotide with single-stranded nucleic acids of non-complementary sequence. For example, specific hybridization can refer to a sequence that hybridizes to any pAID specific marker nucleic acid, but does not hybridize to other nucleotides. Also polynucleotide that “specifically hybridizes” may hybridize only to an airway, colon, immune cell, dendritic, or other tissue specific marker, such as an pAID-specific marker shown in the Tables contained herein. Appropriate conditions enabling specific hybridization of single stranded nucleic acid molecules of varying complementarity are well known in the art.

For instance, one common formula for calculating the stringency conditions required to achieve hybridization between nucleic acid molecules of a specified sequence homology is set forth below (Sambrook et al., Molecular Cloning, Cold Spring Harbor Laboratory (1989): T _(m)=81.5″C+16.6 Log [Na+]+0.41(% G+C)−0.63(% formamide)−600/#bp in duplex As an illustration of the above formula, using [Na+]=[0.368] and 50% formamide, with GC content of 42% and an average probe size of 200 bases, the T_(m) is 57″C. The T_(m) of a DNA duplex decreases by 1-1.5″C with every 1% decrease in homology. Thus, targets with greater than about 75% sequence identity would be observed using a hybridization temperature of 42″C.

The stringency of the hybridization and wash depend primarily on the salt concentration and temperature of the solutions. In general, to maximize the rate of annealing of the probe with its target, the hybridization is usually carried out at salt and temperature conditions that are 20-25° C. below the calculated T_(m) of the hybrid. Wash conditions should be as stringent as possible for the degree of identity of the probe for the target. In general, wash conditions are selected to be approximately 12-20° C. below the T_(m) of the hybrid. In regards to the nucleic acids of the current invention, a moderate stringency hybridization is defined as hybridization in 6×SSC, 5×Denhardt's solution, 0.5% SDS and 100 μg/ml denatured salmon sperm DNA at 42° C., and washed in 2×SSC and 0.5% SDS at 55° C. for 15 minutes. A high stringency hybridization is defined as hybridization in 6×SSC, 5×Denhardt's solution, 0.5% SDS and 100 μg/ml denatured salmon sperm DNA at 42° C., and washed in 1×SSC and 0.5% SDS at 65° C. for 15 minutes. A very high stringency hybridization is defined as hybridization in 6×SSC, 5×Denhardt's solution, 0.5% SDS and 100 μg/ml denatured salmon sperm DNA at 42° C., and washed in 0.1×SSC and 0.5% SDS at 65° C. for 15 minutes.

The term “oligonucleotide,” as used herein is defined as a nucleic acid molecule comprised of two or more ribo- or deoxyribonucleotides, preferably more than three. The exact size of the oligonucleotide will depend on various factors and on the particular application and use of the oligonucleotide. Oligonucleotides, which include probes and primers, can be any length from 3 nucleotides to the full length of the nucleic acid molecule, and explicitly include every possible number of contiguous nucleic acids from 3 through the full length of the polynucleotide. Preferably, oligonucleotides are at least about 10 nucleotides in length, more preferably at least 15 nucleotides in length, more preferably at least about 20 nucleotides in length.

The term “probe” as used herein refers to an oligonucleotide, polynucleotide or nucleic acid, either RNA or DNA, whether occurring naturally as in a purified restriction enzyme digest or produced synthetically, which is capable of annealing with or specifically hybridizing to a nucleic acid with sequences complementary to the probe. A probe may be either single-stranded or double-stranded. The exact length of the probe will depend upon many factors, including temperature, source of probe and use of the method. For example, for diagnostic applications, depending on the complexity of the target sequence, the oligonucleotide probe typically contains 15-25 or more nucleotides, although it may contain fewer or more nucleotides. The probes herein are selected to be complementary to different strands of a particular target nucleic acid sequence. This means that the probes must be sufficiently complementary so as to be able to “specifically hybridize” or anneal with their respective target strands under a set of pre-determined conditions. Therefore, the probe sequence need not reflect the exact complementary sequence of the target. For example, a non-complementary nucleotide fragment may be attached to the 5′ or 3′ end of the probe, with the remainder of the probe sequence being complementary to the target strand. Alternatively, non-complementary bases or longer sequences can be interspersed into the probe, provided that the probe sequence has sufficient complementarity with the sequence of the target nucleic acid to anneal therewith specifically.

The term “primer” as used herein refers to an oligonucleotide, either RNA or DNA, either single-stranded or double-stranded, either derived from a biological system, generated by restriction enzyme digestion, or produced synthetically which, when placed in the proper environment, is able to functionally act as an initiator of template-dependent nucleic acid synthesis. When presented with an appropriate nucleic acid template, suitable nucleoside triphosphate precursors of nucleic acids, a polymerase enzyme, suitable cofactors and conditions such as a suitable temperature and pH, the primer may be extended at its 3′ terminus by the addition of nucleotides by the action of a polymerase or similar activity to yield a primer extension product. The primer may vary in length depending on the particular conditions and requirement of the application. For example, in diagnostic applications, the oligonucleotide primer is typically 15-25 or more nucleotides in length. The primer must be of sufficient complementarity to the desired template to prime the synthesis of the desired extension product, that is, to be able to anneal with the desired template strand in a manner sufficient to provide the 3′ hydroxyl moiety of the primer in appropriate juxtaposition for use in the initiation of synthesis by a polymerase or similar enzyme. It is not required that the primer sequence represent an exact complement of the desired template. For example, a non-complementary nucleotide sequence may be attached to the 5′ end of an otherwise complementary primer. Alternatively, non-complementary bases may be interspersed within the oligonucleotide primer sequence, provided that the primer sequence has sufficient complementarity with the sequence of the desired template strand to functionally provide a template-primer complex for the synthesis of the extension product.

Polymerase chain reaction (PCR) has been described in U.S. Pat. Nos. 4,683,195, 4,800,195, and 4,965,188, the entire disclosures of which are incorporated by reference herein.

The term “siRNA” refers to a molecule involved in the RNA interference process for a sequence-specific post-transcriptional gene silencing or gene knockdown by providing small interfering RNAs (siRNAs) that has homology with the sequence of the targeted gene. Small interfering RNAs (siRNAs) can be synthesized in vitro or generated by ribonuclease III cleavage from longer dsRNA and are the mediators of sequence-specific mRNA degradation. Preferably, the siRNAs of the invention are chemically synthesized using appropriately protected ribonucleoside phosphoramidites and a conventional DNA/RNA synthesizer. The siRNA can be synthesized as two separate, complementary RNA molecules, or as a single RNA molecule with two complementary regions. Commercial suppliers of synthetic RNA molecules or synthesis reagents include Applied Biosystems (Foster City, Calif., USA), Proligo (Hamburg, Germany), Dharmacon Research (Lafayette, Colo., USA), Pierce Chemical (part of Perbio Science, Rockford, Ill., USA), Glen Research (Sterling, Va., USA), ChemGenes (Ashland, Mass., USA) and Cruachem (Glasgow, UK). Specific siRNA constructs for inhibiting mRNAs, for example, may be between 15-35 nucleotides in length, and more typically about 21 nucleotides in length.

The term “vector” relates to a single or double stranded circular nucleic acid molecule that can be infected, transfected or transformed into cells and replicate independently or within the host cell genome. A circular double stranded nucleic acid molecule can be cut and thereby linearized upon treatment with restriction enzymes. An assortment of vectors, restriction enzymes, and the knowledge of the nucleotide sequences that are targeted by restriction enzymes are readily available to those skilled in the art, and include any replicon, such as a plasmid, cosmid, bacmid, phage or virus, to which another genetic sequence or element (either DNA or RNA) may be attached so as to bring about the replication of the attached sequence or element. A nucleic acid molecule of the invention can be inserted into a vector by cutting the vector with restriction enzymes and ligating the two pieces together. When cloning a genetic region containing a duplication or a deletion, the skilled artisan is well aware that flanking sequences upstream and downstream of the affected region of a suitable length would be employed in the cloning process. Such vectors would have utility, for example in cell lines for studying the effects such alterations have on the encoded proteins.

Many techniques are available to those skilled in the art to facilitate transformation, transfection, or transduction of the expression construct into a prokaryotic or eukaryotic organism. The terms “transformation”, “transfection”, and “transduction” refer to methods of inserting a nucleic acid and/or expression construct into a cell or host organism. These methods involve a variety of techniques, such as treating the cells with high concentrations of salt, an electric field, or detergent, to render the host cell outer membrane or wall permeable to nucleic acid molecules of interest, microinjection, PEG-fusion, and the like.

The term “promoter element” describes a nucleotide sequence that is incorporated into a vector that, once inside an appropriate cell, can facilitate transcription factor and/or polymerase binding and subsequent transcription of portions of the vector DNA into mRNA. In one embodiment, the promoter element of the present invention precedes the 5′ end of the pAID specific marker nucleic acid molecule such that the latter is transcribed into mRNA. Host cell machinery then translates mRNA into a polypeptide.

Those skilled in the art will recognize that a nucleic acid vector can contain nucleic acid elements other than the promoter element and the pAID specific marker encoding nucleic acid. These other nucleic acid elements include, but are not limited to, origins of replication, ribosomal binding sites, nucleic acid sequences encoding drug resistance enzymes or amino acid metabolic enzymes, and nucleic acid sequences encoding secretion signals, localization signals, or signals useful for polypeptide purification.

A “replicon” is any genetic element, for example, a plasmid, cosmid, bacmid, plastid, phage or virus, which is capable of replication largely under its own control. A replicon may be either RNA or DNA and may be single or double stranded.

An “expression operon” refers to a nucleic acid segment that may possess transcriptional and translational control sequences, such as promoters, enhancers, translational start signals (e.g., ATG or AUG codons), polyadenylation signals, terminators, and the like, and which facilitate the expression of a polypeptide coding sequence in a host cell or organism.

As used herein, the terms “reporter,” “reporter system”, “reporter gene,” or “reporter gene product” shall mean an operative genetic system in which a nucleic acid comprises a gene that encodes a product that when expressed produces a reporter signal that is a readily measurable, e.g., by biological assay, immunoassay, radio immunoassay, or by colorimetric, fluorogenic, chemiluminescent or other methods. The nucleic acid may be either RNA or DNA, linear or circular, single or double stranded, antisense or sense polarity, and is operatively linked to the necessary control elements for the expression of the reporter gene product. The required control elements will vary according to the nature of the reporter system and whether the reporter gene is in the form of DNA or RNA, but may include, but not be limited to, such elements as promoters, enhancers, translational control sequences, poly A addition signals, transcriptional termination signals and the like.

The introduced nucleic acid may or may not be integrated (covalently linked) into nucleic acid of the recipient cell or organism. In bacterial, yeast, plant and mammalian cells, for example, the introduced nucleic acid may be maintained as an episomal element or independent replicon such as a plasmid. Alternatively, the introduced nucleic acid may become integrated into the nucleic acid of the recipient cell or organism and be stably maintained in that cell or organism and further passed on or inherited to progeny cells or organisms of the recipient cell or organism. Finally, the introduced nucleic acid may exist in the recipient cell or host organism only transiently.

The term “selectable marker gene” refers to a gene that when expressed confers a selectable phenotype, such as antibiotic resistance, on a transformed cell.

The term “operably linked” means that the regulatory sequences necessary for expression of the coding sequence are placed in the DNA molecule in the appropriate positions relative to the coding sequence so as to effect expression of the coding sequence. This same definition is sometimes applied to the arrangement of transcription units and other transcription control elements (e.g. enhancers) in an expression vector.

The terms “recombinant organism” and “transgenic organism” refer to organisms that have a new combination of genes or nucleic acid molecules. A new combination of genes or nucleic acid molecules can be introduced into an organism using a wide array of nucleic acid manipulation techniques available to those skilled in the art. The term “organism” relates to any living being comprised of a least one cell. An organism can be as simple as one eukaryotic cell or as complex as a mammal. Therefore, the phrase “a recombinant organism” encompasses a recombinant cell, as well as eukaryotic and prokaryotic organism.

The term “isolated protein” or “isolated and purified protein” is sometimes used herein. This term refers primarily to a protein produced by expression of an isolated nucleic acid molecule of the invention. Alternatively, this term may refer to a protein that has been sufficiently separated from other proteins with which it would naturally be associated, so as to exist in “substantially pure” form. “Isolated” is not meant to exclude artificial or synthetic mixtures with other compounds or materials, or the presence of impurities that do not interfere with the fundamental activity, and that may be present, for example, due to incomplete purification, addition of stabilizers, or compounding into, for example, immunogenic preparations or pharmaceutically acceptable preparations.

A “specific binding pair” comprises a specific binding member (sbm) and a binding partner (bp) that have a particular specificity for each other and which in normal conditions bind to each other in preference to other molecules. Examples of specific binding pairs are antigens and antibodies, ligands and receptors and complementary nucleotide sequences. The skilled person is aware of many other examples. Further, the term “specific binding pair” is also applicable where either or both of the specific binding member and the binding partner comprise a part of a large molecule. In embodiments in which the specific binding pair comprises nucleic acid sequences, they will be of a length to hybridize to each other under conditions of the assay, preferably greater than 10 nucleotides long, more preferably greater than 15 or 20 nucleotides long.

A “patient” or “subject” as referred to herein may be either an adult (18 or older) or a pediatric subject (under 18). These two terms are generally used interchangeably herein. The patient or subject may be an individual who has been diagnosed with one or more AID, is undergoing AID treatment, or who is seeking a diagnosis of a medical condition due to symptoms of illness, as well as an individual who has not been diagnosed with an AID. For example, in cases where methods are performed to determine susceptibility to developing one or more AID, the subject being tested may be one who does not presently show symptoms of any AID, such as a healthy subject.

“Sample” or “patient sample” or “biological sample” generally refers to a sample that may be tested for a particular molecule, such as an AID specific marker molecule, such as a marker shown in the tables provided below. Samples may include but are not limited to cells, body fluids, including blood, serum, plasma, urine, saliva, tears, pleural fluid and the like.

The terms “agent” and “test compound” are used interchangeably herein and denote a chemical compound, a mixture of chemical compounds, a biological macromolecule, or an extract made from biological materials such as bacteria, plants, fungi, or animal (particularly mammalian) cells or tissues. Biological macromolecules include siRNA, shRNA, antisense oligonucleotides, peptides, peptide/DNA complexes, and any nucleic acid based molecule that exhibits the capacity to modulate the activity of the SNP containing nucleic acids described herein or their encoded proteins. Agents are evaluated for potential biological activity by inclusion in screening assays described herein below.

The term “diagnose” and similar terms such as “diagnosis” or “diagnosing” used when referring to the methods herein encompasses methods, for example, designed to assist in the diagnosis of an AID in conjunction with clinical observations, analysis of symptoms, or other tests for instance, or designed to confirm a diagnosis made based on such other factors or tests. For example, methods herein may be used in conjunction with analysis of symptoms and other tests to provide data that may help a physician to determine if a subject suffers from an AID and if so, which AID or combination AIDs the subject suffers from.

Methods for determining a susceptibility toward developing one or more AIDs are also encompassed herein. In that context, “susceptibility” toward developing an AID means, for example, that the subject is more likely to develop an AID than the population at large. For instance, a genetic alteration as described herein may be a risk factor toward developing an AID at some point in the subject's future.

“Treatment,” as used herein, covers any administration or application of a therapeutic for a disease (also referred to herein as a “disorder” or a “condition”) in a mammal, including a human, and includes inhibiting the disease or progression of the disease, inhibiting or slowing the disease or its progression, arresting its development, partially or fully relieving the disease, partially or fully relieving one or more symptoms of a disease, or restoring or repairing a lost, missing, or defective function; or stimulating an inefficient process.

The term “effective amount” or “therapeutically effective amount” refers to an amount of a drug effective for treatment of a disease or disorder in a subject, such as to partially or fully relieve one or more symptoms. In some embodiments, an effective amount refers to an amount effective, at dosages and for periods of time necessary, to achieve the desired therapeutic or prophylactic result.

An “interaction network” associated with a gene, such as a gene harboring a genetic alteration herein, means that gene as well as genes whose protein products either directly or indirectly bind to, activate, or deactivate the protein product of the gene in question. For example, the network includes genes coding for proteins that bind to the protein product of the gene in question. The network also includes genes coding for proteins that regulate expression, processing, secretion, or biological function of the protein product of the gene in question but that do not directly bind to that protein product.

Methods of Using AID-Associated SNVs for Diagnosing and Treating an AID

Methods of Detecting Genetic Alterations

In some embodiments a genetic alteration in one or more genes may be detected at the nucleic acid level. Any biological sample may be used, including, but not limited to, blood, urine, serum, gastric lavage, CNS fluid, any type of cell (such as brain cells, white blood cells, mononuclear cells) or body tissue. Any biological source material whereby DNA can be extracted may be used. Samples may be freshly collected, or samples may have been previously collected for any use/purpose and stored until the time of testing for genetic alterations. DNA that was previously purified for a different purpose may also be used.

Standard molecular biology methodologies such as quantitative polymerase chain reaction (PCR), droplet PCR, and TaqMan® probes (i.e., hydrolysis probes designed to increase the specificity of quantitative PCR), for example, coupled with sequencing, can be used to assess genetic alterations in a gene. Fluorescent in situ hybridization (FISH) probes may also be used to evaluate genetic alterations.

Various methods for determining genetic alterations are known, including the following below.

Single Nucleotide Variation (SNV)/Single Nucleotide Polymorphism (SNP) Genotyping

Determining whether a patient has a genetic alteration in a gene may be done by SNV/SNP Genotyping, using a SNV/SNP genotyping array such as those commercially available from Illumina or Affymetrix. As noted above, a “single nucleotide variation (SNV),” also interchangeably referred to as a “single nucleotide polymorphism (SNP)” herein, refers to a change in which a single base in the DNA differs from the usual base at that position.

In SNV genotyping, SNVs can be determined by hybridizing complementary DNA probes to the SNV site. A wide range of platforms can be used with SNV genotyping tools to accommodate varying sample throughputs, multiplexing capabilities, and chemistries. In high-density SNV arrays, hundreds of thousands of probes are arrayed on a small chip, such that many SNVs can be interrogated simultaneously when target DNA is processed on the chip. By determining the amount of hybridization of target DNA in a sample to a probe (or redundant probes) on the array, specific SNV alleles can be determined. Use of arrays for SNV genotyping allows the large-scale interrogation of SNVs.

When analyzing CNVs, after SNVs have been analyzed, a computer program must be used to manipulate the SNV data to arrive at CNV data. PennCNV or a similar program can then be used to detect signal patterns across the genome and identify consecutive genetic markers with copy number changes. (See Wang K. and Bucan M. (June 2008) Cold Spring Harb Protoc Vol. 3(6); doi10: 1101/pdb.top46). PennCNV allows for kilobase-resolution detection of CNVs. (See Wang K, et al. (November 2007) Genome Res. 17(11): 1665-74).

In CNV analysis, the SNV genotyping data is compared with the behavior of normal diploid DNA. The software uses SNV genotyping data to determine the signal intensity data and SNV allelic ratio distribution and then uses these data to identify deviations from the normal diploid condition of DNA, indicative of the presence of a CNV. This is done in part by using the log R Ratio (LRR), which is a normalized measure of the total signal intensity for the two alleles of the SNV (Wang 2008). If the software detects regions of contiguous SNVs with intensity (LRR) trending below 0, this indicates a CNV deletion. If the software instead detects regions of contiguous SNVs with intensity (LRR) trending above 0, this indicates a CNV duplication. If no change in LRR is observed compared to the behavior of diploid DNA, the sequence is in the normal diploid state with no CNV present. The software also uses B allele frequency (BAF), a normalized measure of the allelic intensity ratio of two alleles that changes when alleles are lost or gained as with a CNV deletion or duplication. For example, a CNV deletion is indicated by both a decrease in LRR values and a lack of heterozygotes in BAF values. In contrast, a CNV duplication is indicated by both an increase in LRR values and a splitting of the heterozygous genotype BAF clusters into two distinct clusters. The software automates the calculation of LRR and BAF to detect CNV deletions and duplications for whole-genome SNV data. The simultaneous analysis of intensity and genotype data accurately defines the normal diploid state and determines CNVs.

Array platforms such as those from Illumina, Affymetrix, and Agilent may be used in SNV Genotyping. Custom arrays may also be designed and used based on the data described herein.

Comparative Genomic Hybridization

Comparative genomic hybridization (CGH) is another method that may be used to evaluate genetic alterations. CGH is a molecular cytogenetic method for analyzing genetic alterations in comparison to a reference sample using competitive fluorescence in situ hybridization (FISH). DNA is isolated from a patient and a reference source and independently labeled with fluorescent molecules (i.e., fluorophores) after denaturation of the DNA. Hybridization of the fluorophores to the resultant samples is compared along the length of each chromosome to identify chromosomal differences between the two sources. A mismatch of colors indicates a gain or loss of material in the test sample in a specific region, while a match of the colors indicates no difference in genetic alterations such as copy number between the test and reference samples at a particular region.

Sequencing Methods

Whole genome sequencing, whole exome sequencing, or targeted sequencing may also be used to analyze genetic alterations in multiple genes. Whole genome sequencing (also known as full genome sequencing, complete genome sequencing, or entire genome sequencing) involves sequencing of the full genome of a species, including genes that do or do not code for proteins. Whole exome sequencing, in contrast, is sequencing of only the protein-coding genes in the genome (approximately 1% of the genome). Targeted sequencing involves sequencing of only selected parts of the genome.

A wide range of techniques would be known to those skilled in the art to perform whole genome, whole exome, or targeted sequencing with DNA purified from a subject. Similar techniques could be used for different types of sequencing. Techniques used for whole genome sequencing include nanopore technology, fluorophore technology, DNA nanoball technology, and pyrosequencing (i.e., sequencing by synthesis). In particular, next-generation sequencing (NGS) involves sequencing of millions of small fragments of DNA in parallel followed by use of bioinformatics analyses to piece together sequencing data from the fragments.

As whole exome sequencing does not need to sequence as large an amount of DNA as whole genome sequencing, a wider range of techniques are may be used. Methods for whole exome sequencing include polymerase chain reaction methods, NGS methods, molecular inversion probes, hybrid capture using microarrays, in-solution capture, and classical Sanger sequencing. Targeted sequencing allows for providing sequence data for specific genes rather than whole genomes and can use any of the techniques used for other types of sequencing, including specialized microarrays containing materials for sequencing genes of interest. Proprietary methodologies, such as those from BioNano or OpGen, using genome mapping technology can also be used to evaluate genetic alterations.

AID-related SNV-containing nucleic acids, including but not limited to those listed in the Tables provided below may be used for a variety of purposes in accordance with the present invention. AID-associated SNV-containing DNA, RNA, or fragments thereof may be used as probes to detect the presence of and/or expression of AID specific markers. Methods in which AID specific marker nucleic acids may be utilized as probes for such assays include, but are not limited to: (1) in situ hybridization; (2) Southern hybridization (3) northern hybridization; and (4) assorted amplification reactions such as polymerase chain reactions (PCR).

Further, assays for detecting AID-associated SNVs or the proteins encoded thereby may be conducted on any type of biological sample, including but not limited to body fluids (including blood, urine, serum, gastric lavage), any type of cell (such as brain cells, white blood cells, mononuclear cells) or body tissue.

From the foregoing discussion, it can be seen that AID-associated SNV containing nucleic acids, vectors expressing the same, AID SNV containing marker proteins and anti-AID specific marker antibodies of the invention can be used to detect AID associated SNVs in body tissue, cells, or fluid, and alter AID SNV containing marker protein expression for purposes of assessing the genetic and protein interactions involved in the development of AID.

In most embodiments for screening for AID-associated SNVs, the AID-associated SNV containing nucleic acid in the sample will initially be amplified, e.g. using PCR, to increase the amount of the templates as compared to other sequences present in the sample. This allows the target sequences to be detected with a high degree of sensitivity if they are present in the sample. This initial step may be avoided by using highly sensitive array techniques that are becoming increasingly important in the art.

Alternatively, new detection technologies can overcome this limitation and enable analysis of small samples containing as little as 1 μg of total RNA. Using Resonance Light Scattering (RLS) technology, as opposed to traditional fluorescence techniques, multiple reads can detect low quantities of mRNAs using biotin labeled hybridized targets and anti-biotin antibodies. Another alternative to PCR amplification involves planar wave guide technology (PWG) to increase signal-to-noise ratios and reduce background interference. Both techniques are commercially available from Qiagen Inc. (USA).

Thus any of the aforementioned techniques may be used to detect or quantify AID-associated SNV marker expression and accordingly, diagnose AID.

Associations of Particular Genetic Alterations with One or More AIDs

As described in the Examples, figures, and tables below, studies of the inventors on pediatric subjects identified 27 genome-wide significant (GWS) loci wherein genetic alterations are associated with presence of one or more pAID. In addition, there were 46 loci that reached at least genome-wide marginal significance (GWM) in associations with particular pAIDs. Thus, the present disclosure encompasses methods of identifying genetic alterations such as SNVs at these GWS and GWM loci, for example, to assist in determining appropriate treatments for AID patients with those genetic alterations or to diagnose one or more AIDs in patients, or to determine whether a subject is susceptible to developing one or more AIDs in the future.

For example, in some embodiments involving subjects with ankylosing spondylitis (AS), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from an AS patient and detecting the presence of a genetic alteration in one or more of IL23R, TNM3, LRRK2, SBK1, IL2RA, ZMIZ1, IL21, or CARD9. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of IL23R, TNM3, LRRK2, SBK1, IL2RA, ZMIZ1, IL21, or CARD9 in order to diagnose AS or determine if the subject has a propensity to develop AS. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, genetic alterations in, for example, one or more of CRB1, GPR35, CYTL3, IL12B, 8q24.23, JAK2, FNBP1, or SMAD3 are also assessed. (See Table 2b.) In some embodiments, the detected genetic alteration is used to determine treatment options for the AS patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the AS patient is administered a drug targeting the gene in which the genetic alteration is found. For example, the drug may target the pathway of that gene in order to influence the pathway in a way that compensates for the genetic alteration.

Similarly, in some embodiments involving subjects with psoriasis (PS), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from a PS patient and detecting the presence of a genetic alteration in one or more of IL23R, PTPN22, TNM3, DAG1, ATG16L1, SUOX, SBK1, ADCY7, IL2RA, or ZMIZ1. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of IL23R, PTPN22, TNM3, DAG1, ATG16L1, SUOX, SBK1, ADCY7, IL2RA, or ZMIZ1 in order to diagnose PS or determine if the subject has a propensity to develop PS. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, genetic alterations in, for example, one or more of IL10, TSSC1, IL5, IL2RA, ADCY7, FUT2, and TNFRSF6B are also assessed. (See Table 2b.) In some embodiments, the detected genetic alteration is used to determine treatment options for the PS patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the PS patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with celiac disease (CEL), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from a CEL patient and detecting the presence of a genetic alteration in one or more of TNM3, DAG1, SBK1, IL2RA, C40LG, ZMIZ1, or IL21. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of TNM3, DAG1, SBK1, IL2RA, C40LG, ZMIZ1, or IL21 in order to diagnose CEL or determine if the subject has a propensity to develop CEL. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, genetic alterations in, for example, one or more of IL18R1, CYTL1, ERAP2, IL5, IL12B, 8q24.23, IKZF3, CD40LG, or RBMX are also assessed. (See Table 2b.) In some embodiments, the detected genetic alteration is used to determine treatment options for the CEL patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the CEL patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with systemic lupus erythematosus (SLE), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from an SLE patient and detecting the presence of a genetic alteration in one or both of PTPN22 or TNM3. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of PTPN22 or TNM3 in order to diagnose SLE or determine if the subject has a propensity to develop SLE. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, genetic alterations in, for example, one or more of IL10, TSSC1, GPR35, JAK2, ZNF365, TYK2, or TNFRSF6B are also assessed. (See Table 2b.) In some embodiments, the detected genetic alteration is used to determine treatment options for the SLE patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the SLE patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with common variable immunodeficiency (CVID), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from a CVID patient and detecting the presence of a genetic alteration in one or more of LPHN2, TNM3, or IL21. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of LPHN2, TNM3, or IL21 in order to diagnose CVID or determine if the subject has a propensity to develop CVID. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, genetic alterations in, for example, one or both of EFNB2 or IKZF3 are also assessed. (See Table 2b.) In some embodiments, the detected genetic alteration is used to determine treatment options for the CVID patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein). Thus, in some embodiments, the CVID patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with ulcerative colitis (UC), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from a UC patient and detecting the presence of a genetic alteration in one or more of IL23R, LPHN2, DAG1, PTGER4, SBK1, TNFSF15, CD40LG, IL21, CARD9, or PSMG1. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of IL23R, LPHN2, DAG1, PTGER4, SBK1, TNFSF15, CD40LG, IL21, CARD9, or PSMG1 in order to diagnose UC or determine if the subject has a propensity to develop UC. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, genetic alterations in, for example, one or more of IL10, TSSC1, IL18R1, GPR35, CYTL1, IL12B, JAK2, NKX2, SMAD3, ATXN2L, IKZF3, or TNFRSF6B are also assessed. (See Table 2b.) In some embodiments, the detected genetic alteration is used to determine treatment options for the UC patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the UC patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with Type 1 diabetes (T1D), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from a T1D patient and detecting the presence of a genetic alteration in one or more of PTPN22, INS, SUOX, IL2RA, or IL21. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of PTPN22, INS, SUOX, IL2RA, or IL21 in order to diagnose T1D or determine if the subject has a propensity to develop T1D. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, genetic alterations in, for example, one or more of CYTL1, 8q24.23, TYK2, or FUT2 are also assessed. (See Table 2b.) In some embodiments, the detected genetic alteration is used to determine treatment options for the T1D patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the T1D patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with juvenile idiopathic arthritis (JIA), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from a JIA patient and detecting the presence of a genetic alteration in one or more of LPHN2, PTPN22, TNM3, ANKRD30A, ANKRD55, IL2RA, CD40LG, or IL21. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of LPHN2, PTPN22, TNM3, ANKRD30A, ANKRD55, IL2RA, CD40LG, or IL21 in order to diagnose J1A or determine if the subject has a propensity to develop JIA. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, genetic alterations in, for example, one or more of CYTL1, ERAP2, 8q24.23, LURAP1L, FNBP1, EFNB2, IKZF3, TYK2, or RBMX are also assessed. (See Table 2b.) In some embodiments, the detected genetic alteration is used to determine treatment options for the JIA patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the JIA patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with Crohn's disease (CD), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from a CD patient and detecting the presence of a genetic alteration in one or more of IL23R, PTPN22, DAG1, ATG16L1, PTGER4, ANKRD55, LRRK2, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, or PSMG1. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of IL23R, PTPN22, DAG1, ATG16L1, PTGER4, ANKRD55, LRRK2, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, or PSMG1 in order to diagnose CD or determine if the subject has a propensity to develop CD. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, genetic alterations in, for example, one or more of CRB1, IL10, TSSC1, IL18R1, CYTL1, ERAP2, IL5, IL12B, 8q24.23, JAK2, FNBP1, ZNF365, NKX2, SMAD3, ATXN2L, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, or RBMX are also assessed. (See Table 2b.) In some embodiments, the detected genetic alteration is used to determine treatment options for the CD patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the CD patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with alopecia areata (AA), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from an AA patient and detecting the presence of a genetic alteration in one or both of IL2RA or IL21. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of IL2RA or IL21 in order to diagnose AA or determine if the subject has a propensity to develop AA. In some embodiments, the detected genetic alteration is used to determine treatment options for the AA patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the AA patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with multiple sclerosis (MS), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from an MS patient and detecting the presence of a genetic alteration in one or more of PTGER4, ANKRD55, IL2RA, CD40LG, or ZMIZ1. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of PTGER4, ANKRD55, IL2RA, CD40LG, or ZMIZ1 in order to diagnose MS or determine if the subject has a propensity to develop MS. In some embodiments, the detected genetic alteration is used to determine treatment options for the MS patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the MS patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with primary sclerosing cholangitis (PSC), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from a PSC patient and detecting the presence of a genetic alteration in one or both of IL2A or IL21. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of IL2A or IL21 in order to diagnose PSC or determine if the subject has a propensity to develop PSC. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, the detected genetic alteration is used to determine treatment options for the PSC patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the PSC patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with rheumatoid arthritis (RA), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from an RA patient and detecting the presence of a genetic alteration in one or more of PTPN22, ANKRD55, IL2RA, or IL21. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of PTPN22, ANKRD55, IL2RA, or IL21 in order to diagnose RA or determine if the subject has a propensity to develop RA. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, the detected genetic alteration is used to determine treatment options for the RA patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the RA patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with vitiligo (VIT), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from a VIT patient and detecting the presence of a genetic alteration in one or more of PTPN22 or IL2RA. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of PTPN22 or IL2RA in order to diagnose VIT or determine if the subject has a propensity to develop VIT. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, the detected genetic alteration is used to determine treatment options for the VIT patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the VIT patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments involving subjects with thyroiditis (THY), a method of detecting the presence of a genetic alteration, such as an SNV, is provided comprising obtaining a biological sample from a THY patient and detecting the presence of a genetic alteration in one or more of PTPN22, TNM3, SBK1, IL2RA, or IL21. (See Supplemental Table 1b.) Alternatively, in some embodiments a method is provided comprising obtaining a biological sample from a subject and detecting the presence of a genetic alteration in one or more of PTPN22, TNM3, SBK1, IL2RA, or IL21 in order to diagnose THY or determine if the subject has a propensity to develop THY. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, genetic alterations in, for example, one or more of IL18R1, CYTL1, FNBP1, IKZF3, TYK2, or TNFRSF6B are also assessed. (See Table 2b.) In some embodiments, the detected genetic alteration is used to determine treatment options for the THY patient, for example, to administer a drug targeting a gene in the pathway of the altered gene. (See Tables 11 and 12 for agents targeting particular identified genes herein.) Thus, in some embodiments, the THY patient is administered a drug targeting the gene in which the genetic alteration is found.

In some embodiments, samples from pediatric or adult patients diagnosed with one or more of AS, PS, CEL, SLE, CVID, UC, T1D, JIA, CD, AA, MS, primary biliary cirrhosis (PBC), primary sclerosing cholangitis (PSC), RA, Sjogren's syndrome (SJO), systemic sclerosis (SSC), vitiligo (VIT), or THY may be assessed for genetic alterations such as SNVs in one or more of IL23R, LPHN2, PTPN22, TNM3, ANKRD30A, INS, NOD2, DAG1, SMAD3, ATG16L1, ZNF365, PTGER4, NKX2 or 3, ANKRD55, IL12B, LRRK2, IL5, SUOX, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, or PSMG1. (See Supplemental Table 1b.) In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, at least 5, such as at least 10, at least 15, or at least 20 of the above genes are assessed for genetic alterations. In some embodiments, samples from pediatric or adult subjects may be assessed for genetic alterations such as SNVs in one or more of IL23R, LPHN2, PTPN22, TNM3, ANKRD30A, INS, NOD2, DAG1, SMAD3, ATG16L1, ZNF365, PTGER4, NKX2 or 3, ANKRD55, IL12B, LRRK2, IL5, SUOX, SBK1, ADCY7, IL2RA, TNFSF15, CD40LG, ZMIZ1, IL21, CARD9, or PSMG1 in order to diagnose one or more AIDs or determine susceptibility to development of an AID. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, at least 5, such as at least 10, at least 15, or at least 20 of the above genes are assessed for genetic alterations.

In some embodiments, samples from pediatric or adult patients diagnosed with one or more of AS, PS, CEL, SLE, CVID, UC, T1D, JIA, CD, AA, MS, primary biliary cirrhosis (PBC), primary sclerosing cholangitis (PSC), RA, Sjogren's syndrome (SJO), systemic sclerosis (SSC), vitiligo (VIT), or THY may be assessed for genetic alterations such as SNVs in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, or RBMX. (See Supplemental Table 1b.) In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, at least 5, such as at least 10, at least 15, at least 20, at least 25, at least 30, at least 35, or at least 40 of the above genes are assessed for genetic alterations. In some embodiments, samples from pediatric or adult subjects may be assessed for genetic alterations such as SNVs in one or more of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARD9, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, CD40LG, or RBMX in order to diagnose or determine susceptibility to development of an AID. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, at least 5, such as at least 10, at least 15, at least 20, at least 25, at least 30, at least 35, or at least 40 of the above genes are assessed for genetic alterations.

In some of the above embodiments, samples from pediatric or adult patients diagnosed with one or more of AS, PS, CEL, SLE, CVID, US, T1D, JIA, CD, AA, MS, primary biliary cirrhosis (PBC), primary sclerosing cholangitis (PSC), RA, Sjogren's syndrome (SJO), systemic sclerosis (SSC), vitiligo (VIT), or THY may be assessed for genetic alterations such as SNVs in one or more of LPHN2, TNM3, ANKRD30A, ADCY7, or CD40LG. (See Supplemental Tables 1b and 1c.) In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed. In some embodiments, samples from pediatric or adult subjects may be assessed for genetic alterations such as SNVs in one or more of LPHN2, TNM3, ANKRD30A, ADCY7, or CD40LG in order to determine susceptibility to development of an AID. In some embodiments, genetic alterations in all of those genes are assessed. In some embodiments, one or more of those genes is not assessed.

In some embodiments, in order to diagnose, determine treatment for, or determine susceptibility towards either UC or PSC, genetic alterations in at least one of, such as 2, 3, 4, or all of, the following genes are also assessed: ICAM1, CD40, JAK2, TYK2, and IL12B. In some embodiments, in order to diagnose, determine treatment for, or determine susceptibility towards either MS or CEL, genetic alterations in at least one, 2, 3, or all of the following genes are assessed: IL19, IL20, STAT5A, and IL2RA. In some embodiments, in order to diagnose, determine treatment for, or determine susceptibility towards either SLE or PSC, genetic alterations in at least one, two, three, or all of the following genes are assessed: ILF3, CENPO, MEDI, and NCDA3. These genes may be screened, for instance, in addition to those associated with these diseases above.

Treatment of Subjects Harboring Genetic Alterations

In some embodiments, AID patients who are found to harbor one or more genetic alterations in the above genes may be directed to particular treatments that are targeted toward the pathway in which the products of the altered genes are included. Some embodiments herein include a method of first diagnosing AID in a patient through checking for one or more of the above genetic alterations or determining if a previously diagnosed AID patient has one or more of the above genetic alterations, and then, if such an alteration is present, providing a report with information about particular treatments that target the pathway associated with the product of the altered gene or genes. In some embodiments, the methods include administering such a treatment to the patient.

For example, Tables 11 and 12 herein list molecules that are on the U.S. market or in pre-clinical or clinical development that target particular genes or pathways.

For example, if an AID patient is found to have a genetic alteration in a gene in a particular pathway, such as in the CD40 pathway, such as an alteration in CD40LG, the patient may be directed to treatment with a therapeutic targeting that pathway, such as a CD40 inhibitor, such as an anti-CD40 antibody, an anti-CD40LG antibody, or other inhibitor of a CD40 pathway molecule. If an AID patient is found to have a genetic alteration, for example, in a gene in the JAK-STAT pathway, the patient may be directed to treatment with a therapeutic targeting the JAK-STAT pathway. If an AID patient is found to have a genetic alteration, for example, in a gene in the TNF superfamily such as in TNFSF15, the patient may be directed to treatment with a therapeutic targeting a TNF superfamily member pathway, such as a therapeutic targeting the pathway involving TNFSF15.

If an AID patient is found to have a genetic alteration, for example, in LRRK2, the patient may be directed to a therapeutic targeting LRRK2, such as those listed in Table 12. If an AID patient is found to have a genetic alteration, for example, in IL-21, the patient may be directed to a therapeutic targeting IL-21, such as those listed in Table 12. If an AID patient is found to have a genetic alteration, for example, in ADCY7, the patient may be directed to a therapeutic targeting ADCY7, such as those listed in Table 12. If an AID patient is found to have a genetic alteration, for example, in SMAD3, the patient may be directed to a therapeutic targeting SMAD3, such as that listed in Table 12. If an AID patient is found to have a genetic alteration, for example, in NOD2, the patient may be directed to a therapeutic targeting NOD2, such as those listed in Table 12. If an AID patient is found to have a genetic alteration, for example, in IL2RA, the patient may be directed to a therapeutic targeting IL2RA, such as those listed in Table 12.

Furthermore, some of the genes described herein encode proteins involved in the IL3, IL5, and/or GM-CSF signaling pathways, such as IL5, IL23R, INS, IL12B, ADCY7, IL2RA, and TNFSF15. Thus, if an AID patient is found to have a genetic alteration in one of these genes, the patient may be directed to a therapeutic targeting those pathways.

Otherwise, a patient may be directed to a treatment targeting a molecule that is within the interaction network of the gene harboring the genetic alteration. This may be a treatment targeting the altered gene (or its gene product) itself or targeting a molecule that binds to the product of the altered gene or that upregulates or downregulates the product of the altered gene or that upregulates or downregulates a protein that interacts with (e.g. binds, activates, or deactivates) the product of the altered gene.

As described in Example 1 below, the inventors have also discovered links between different pAID through common genetic etiologies. For example, several genetic alterations may be shared between subjects with J1A and CVID, e.g. alterations in LPHN2, TNM3, and IL21. Alterations in LPHN2 have also been observed in subjects with PSC, and thus, the methods herein may be used to identify subjects with J1A, CVID, and/or PSC who are at risk of developing one of these other AIDs. Alterations may be shared between subjects with J1A, T1D, and CEL, such as in IL2RA and IL21. Alterations may be shared between subjects with T1D and UC, such as in IL21, between CEL and UC, such as in DAG1, IL12B, SBK1, CD40LG, and IL21. Alterations may be shared between subjects with J1A and UC, such as in IL21. In these cases, methods of assessing genetic alterations in these genes may be performed in a patient diagnosed with one of these diseases in order to determine if the subject is susceptible to developing another AID such as one associated with the same genetic alterations.

Kits and Articles of Manufacture

This disclosure also encompasses kits and articles of manufacture, which may be used, for example, to test subjects for genetic alterations in one or more of the above genes. For example, in some embodiments, solid support matrices may be used containing reagents necessary to identify the genetic alterations, such as particular polynucleotide sequences that are capable of recognizing an SNV and/or CNV in one or more of the genes, such as an AID-associated SNV specific marker polynucleotide that could act as a probe to detect an SNV and/or CNV. In some embodiments, the solid support matrices may be in the form of chips. Any of the aforementioned products can be incorporated into a kit, which may contain an AID-associated SNV specific marker polynucleotide or one or more such markers immobilized on a solid support matrix such as a Gene Chip. A kit could also include molecules such as an oligonucleotide, a polypeptide, a peptide, an antibody, a label, marker, or reporter, a pharmaceutically acceptable carrier, a physiologically acceptable carrier, instructions for use, a container, a vessel for administration, an assay substrate, or any combination thereof, and a kit may also contain instructions for use.

In some embodiments, such a solid support or kit may be part of a system for carrying out one or more of the methods disclosed herein. For example, a solid support or kit with reagents needed to determine the presence of one or more genetic alterations discussed herein may be used for this portion of the methods herein.

Methods of Using AID-Associated SNVs for Development of Therapeutic Agents

Since the SNVs identified herein have been associated with the etiology of AID, methods for identifying agents that modulate the activity of the genes and their encoded products containing such SNVs may result in the generation of efficacious therapeutic agents for the treatment of this condition.

The chromosomal regions described herein contain protein coding regions which provide suitable targets for the rational design of therapeutic agents which modulate their activity. Small peptide molecules corresponding to these regions may be used to advantage in the design of therapeutic agents that may effectively modulate the activity of the encoded proteins.

Molecular modeling may facilitate the identification of specific organic molecules with capacity to bind to the active site of the proteins encoded by the SNV containing nucleic acids based on conformation or key amino acid residues required for function. A combinatorial chemistry approach may be used to identify molecules with greatest activity and then iterations of these molecules will be developed for further cycles of screening. In certain embodiments, candidate drugs can be screened from large libraries of synthetic or natural compounds. One example is an FDA approved library of compounds that can be used by humans. In addition, compound libraries are commercially available from a number of companies including but not limited to Maybridge Chemical Co. (Trevillet, Cornwall, UK), Comgenex (Princeton, N.J.), Microsource (New Milford, Conn.), Aldrich (Milwaukee, Wis.), AKos Consulting and Solutions GmbH (Basel, Switzerland), Ambinter (Paris, France), Asinex (Moscow, Russia), Aurora (Graz, Austria), BioFocus DPI, Switzerland, Bionet (Camelford, UK), ChemBridge, (San Diego, Calif.), ChemDiv, (San Diego, Calif.), Chemical Block Lt, (Moscow, Russia), ChemStar (Moscow, Russia), Exclusive Chemistry, Ltd (Obninsk, Russia), Enamine (Kiev, Ukraine), Evotec (Hamburg, Germany), Indofine (Hillsborough, N.J.), Interbioscreen (Moscow, Russia), Interchim (Montlucon, France), Life Chemicals, Inc. (Orange, Conn.), Microchemistry Ltd. (Moscow, Russia), Otava, (Toronto, ON), PharmEx Ltd. (Moscow, Russia), Princeton Biomolecular (Monmouth Junction, N.J.), Scientific Exchange (Center Ossipee, N.H.), Specs (Delft, Netherlands), TimTec (Newark, Del.), Toronto Research Corp. (North York ON), UkrOrgSynthesis (Kiev, Ukraine), Vitas-M, (Moscow, Russia), Zelinsky Institute, (Moscow, Russia), and Bicoll (Shanghai, China).

Libraries of natural compounds in the form of bacterial, fungal, plant and animal extracts are commercially available or can be readily prepared by methods well known in the art. It is proposed that compounds isolated from natural sources, such as animals, bacteria, fungi, plant sources, including leaves and bark, and marine samples may be assayed as candidates for the presence of potentially useful pharmaceutical agents. It will be understood that the pharmaceutical agents to be screened could also be derived or synthesized from chemical compositions or man-made compounds. Several commercial libraries can be used in the screens.

The polypeptides or fragments employed in drug screening assays may either be free in solution, affixed to a solid support or within a cell. One method of drug screening utilizes eukaryotic or prokaryotic host cells which are stably transformed with recombinant polynucleotides expressing the polypeptide or fragment, preferably in competitive binding assays. Such cells, either in viable or fixed form, can be used for standard binding assays. One may determine, for example, formation of complexes between the polypeptide or fragment and the agent being tested, or examine the degree to which the formation of a complex between the polypeptide or fragment and a known substrate is interfered with by the agent being tested.

Another technique for drug screening provides high throughput screening for compounds having suitable binding affinity for the encoded polypeptides and is described in detail in Geysen, PCT published application WO 84/03564, published on Sep. 13, 1984. Briefly stated, large numbers of different, small peptide test compounds, such as those described above, are synthesized on a solid substrate, such as plastic pins or some other surface. The peptide test compounds are reacted with the target polypeptide and washed. Bound polypeptide is then detected by methods well known in the art.

A further technique for drug screening involves the use of host eukaryotic cell lines or cells (such as airway smooth muscle cells, immune cells, dendritic cells, colon cells, etc.) that have a nonfunctional or altered AID associated gene. These host cell lines or cells are defective at the polypeptide level. The host cell lines or cells are grown in the presence of drug compound.

Host cells contemplated for use in the present invention include but are not limited to bacterial cells, fungal cells, insect cells, and any suitable type of mammalian cell. The AID-associated SNV encoding DNA molecules may be introduced singly into such host cells or in combination to assess the phenotype of cells conferred by such expression. Methods for introducing DNA molecules are also well known to those of ordinary skill in the art. Such methods are set forth in Ausubel et al. eds., Current Protocols in Molecular Biology, John Wiley & Sons, NY, N.Y. 1995, the disclosure of which is incorporated by reference herein.

A wide variety of expression vectors are available that can be modified to express the novel DNA sequences of this invention. The specific vectors exemplified herein are merely illustrative, and are not intended to limit the scope of the invention. Expression methods are described by Sambrook et al. Molecular Cloning: A Laboratory Manual or Current Protocols in Molecular Biology 16.3-17.44 (1989). Expression methods in Saccharomyces are also described in Current Protocols in Molecular Biology (1989).

Suitable vectors for use in practicing the invention include prokaryotic vectors such as the pNH vectors (Stratagene Inc., 11099 N. Torrey Pines Rd., La Jolla, Calif. 92037), pET vectors (Novogen Inc., 565 Science Dr., Madison, Wis. 53711) and the pGEX vectors (Pharmacia LKB Biotechnology Inc., Piscataway, N.J. 08854). Examples of eukaryotic vectors useful in practicing the present invention include the vectors pRc/CMV, pRc/RSV, and pREP (Invitrogen, 11588 Sorrento Valley Rd., San Diego, Calif. 92121); pcDNA3.1/V5&His (Invitrogen); and yeast vectors such as YRP17, YIPS, and YEP24 (New England Biolabs, Beverly, Mass.), as well as pRS403 and pRS413 Stratagene Inc.); retroviral vectors such as PLNCX and pLPCX (Clontech); and adenoviral and adeno-associated viral vectors.

Promoters for use in expression vectors of this invention include promoters that are operable in prokaryotic or eukaryotic cells. Promoters that are operable in prokaryotic cells include lactose (lac) control elements, bacteriophage lambda (pL) control elements, arabinose control elements, tryptophan (trp) control elements, bacteriophage T7 control elements, and hybrids thereof. Promoters that are operable in eukaryotic cells include Epstein Barr virus promoters, adenovirus promoters, SV40 promoters, Rous Sarcoma Virus promoters, cytomegalovirus (CMV) promoters, and Saccharomyces promoters such as the gal4 inducible promoter and the PGK constitutive promoter. In addition, a vector of this invention may contain any one of a number of various markers facilitating the selection of a transformed host cell. Such markers include genes associated with temperature sensitivity, drug resistance, or enzymes associated with phenotypic characteristics of the host organisms.

Host cells expressing the AID-associated SNVs of the present invention or functional fragments thereof provide a system in which to screen potential compounds or agents for the ability to modulate the development of AID. Thus, in one embodiment, the nucleic acid molecules of the invention may be used to create recombinant cell lines for use in assays to identify agents which modulate aspects of aberrant cytokine signaling associated with AID and/or aberrant bronchoconstriction. Also provided herein are methods to screen for compounds capable of modulating the function of proteins encoded by SNV containing nucleic acids.

Another approach entails the use of phage display libraries engineered to express fragment of the polypeptides encoded by the SNV containing nucleic acids on the phage surface. Such libraries are then contacted with a combinatorial chemical library under conditions wherein binding affinity between the expressed peptide and the components of the chemical library may be detected. U.S. Pat. Nos. 6,057,098 and 5,965,456 provide methods and apparatus for performing such assays.

The goal of rational drug design is to produce structural analogs of biologically active polypeptides of interest or of small molecules with which they interact (e.g., agonists, antagonists, inhibitors) in order to fashion drugs which are, for example, more active or stable forms of the polypeptide, or which, e.g., enhance or interfere with the function of a polypeptide in vivo. See, e.g., Hodgson, (1991) Bio/Technology 9:19-21. In one approach, discussed above, the three-dimensional structure of a protein of interest or, for example, of the protein-substrate complex, is solved by x-ray crystallography, by nuclear magnetic resonance, by computer modeling or most typically, by a combination of approaches. Less often, useful information regarding the structure of a polypeptide may be gained by modeling based on the structure of homologous proteins. An example of rational drug design is the development of HIV protease inhibitors (Erickson et al., (1990) Science 249:527-533). In addition, peptides may be analyzed by an alanine scan (Wells, (1991) Meth. Enzym. 202:390-411). In this technique, an amino acid residue is replaced by Ala, and its effect on the peptide's activity is determined. Each of the amino acid residues of the peptide is analyzed in this manner to determine the important regions of the peptide.

It is also possible to isolate a target-specific antibody, selected by a functional assay, and then to solve its crystal structure. In principle, this approach yields a pharmacore upon which subsequent drug design can be based.

One can bypass protein crystallography altogether by generating anti-idiotypic antibodies (anti-ids) to a functional, pharmacologically active antibody. As a mirror image of a mirror image, the binding site of the anti-ids would be expected to be an analog of the original molecule. The anti-id could then be used to identify and isolate peptides from banks of chemically or biologically produced banks of peptides. Selected peptides would then act as the pharmacore.

Thus, one may design drugs that have, e.g., improved polypeptide activity or stability or which act as inhibitors, agonists, antagonists, etc. of polypeptide activity. By virtue of the availability of SNV containing nucleic acid sequences described herein, sufficient amounts of the encoded polypeptide may be made available to perform such analytical studies as x-ray crystallography. In addition, the knowledge of the protein sequence provided herein will guide those employing computer modeling techniques in place of, or in addition to x-ray crystallography.

In another embodiment, the availability of AID-associated SNV containing nucleic acids enables the production of strains of laboratory mice carrying the AID-associated SNVs of the invention. Transgenic mice expressing the AID-associated SNV of the invention may provide a model system in which to examine the role of the protein encoded by the SNV containing nucleic acid in the development and progression towards AID. Methods of introducing transgenes in laboratory mice are known to those of skill in the art. Three common methods include: 1. integration of retroviral vectors encoding the foreign gene of interest into an early embryo; 2. injection of DNA into the pronucleus of a newly fertilized egg; and 3. incorporation of genetically manipulated embryonic stem cells into an early embryo. Production of the transgenic mice described above will facilitate the molecular elucidation of the role that a target protein plays in various processes associated with the AID phenotypes. Such mice provide an in vivo screening tool to study putative therapeutic drugs in a whole animal model and are encompassed by the present invention.

The term “animal” is used herein to include all vertebrate animals, except humans. It also includes an individual animal in all stages of development, including embryonic and fetal stages. A “transgenic animal” is any animal containing one or more cells bearing genetic information altered or received, directly or indirectly, by deliberate genetic manipulation at the subcellular level, such as by targeted recombination or microinjection or infection with recombinant virus. The term “transgenic animal” is not meant to encompass classical cross-breeding or in vitro fertilization, but rather is meant to encompass animals in which one or more cells are altered by or receive a recombinant DNA molecule. This molecule may be specifically targeted to a defined genetic locus, be randomly integrated within a chromosome, or it may be extrachromosomally replicating DNA. The term “germ cell line transgenic animal” refers to a transgenic animal in which the genetic alteration or genetic information was introduced into a germ line cell, thereby conferring the ability to transfer the genetic information to offspring. If such offspring, in fact, possess some or all of that alteration or genetic information, then they, too, are transgenic animals.

The alteration of genetic information may be foreign to the species of animal to which the recipient belongs, or foreign only to the particular individual recipient, or may be genetic information already possessed by the recipient. In the last case, the altered or introduced gene may be expressed differently than the native gene. Such altered or foreign genetic information would encompass the introduction of AID-associated SNV containing nucleotide sequences.

The DNA used for altering a target gene may be obtained by a wide variety of techniques that include, but are not limited to, isolation from genomic sources, preparation of cDNAs from isolated mRNA templates, direct synthesis, or a combination thereof.

A preferred type of target cell for transgene introduction is the embryonal stem cell (ES). ES cells may be obtained from pre-implantation embryos cultured in vitro (Evans et al., (1981) Nature 292:154-156; Bradley et al., (1984) Nature 309:255-258; Gossler et al., (1986) Proc. Natl. Acad. Sci. 83:9065-9069). Transgenes can be efficiently introduced into the ES cells by standard techniques such as DNA transfection or by retrovirus-mediated transduction. The resultant transformed ES cells can thereafter be combined with blastocysts from a non-human animal. The introduced ES cells thereafter colonize the embryo and contribute to the germ line of the resulting chimeric animal.

One approach to the problem of determining the contributions of individual genes and their expression products is to use isolated AID-associated SNV genes as insertional cassettes to selectively inactivate a wild-type gene in totipotent ES cells (such as those described above) and then generate transgenic mice. The use of gene-targeted ES cells in the generation of gene-targeted transgenic mice was described, and is reviewed elsewhere (Frohman et al., (1989) Cell 56:145-147; Bradley et al., (1992) Bio/Technology 10:534-539).

Techniques are available to inactivate or alter any genetic region to a mutation desired by using targeted homologous recombination to insert specific changes into chromosomal alleles. However, in comparison with homologous extrachromosomal recombination, which occurs at a frequency approaching 100%, homologous plasmid-chromosome recombination was originally reported to only be detected at frequencies between 10⁻⁶ and 10⁻³. Non-homologous plasmid-chromosome interactions are more frequent occurring at levels 10⁵-fold to 10² fold greater than comparable homologous insertion.

To overcome this low proportion of targeted recombination in murine ES cells, various strategies have been developed to detect or select rare homologous recombinants. One approach for detecting homologous alteration events uses the polymerase chain reaction (PCR) to screen pools of transformant cells for homologous insertion, followed by screening of individual clones. Alternatively, a positive genetic selection approach has been developed in which a marker gene is constructed which will only be active if homologous insertion occurs, allowing these recombinants to be selected directly. One of the most powerful approaches developed for selecting homologous recombinants is the positive-negative selection (PNS) method developed for genes for which no direct selection of the alteration exists. The PNS method is more efficient for targeting genes that are not expressed at high levels because the marker gene has its own promoter. Non-homologous recombinants are selected against by using the Herpes Simplex virus thymidine kinase (HSV-TK) gene and selecting against its nonhomologous insertion with effective herpes drugs such as gancyclovir (GANC) or (1-(2-deoxy-2-fluoro-B-D arabinofluranosyl)-5-iodou-racil, (FIAU). By this counter selection, the number of homologous recombinants in the surviving transformants can be increased. Utilizing AID-associated SNV containing nucleic acid as a targeted insertional cassette provides means to detect a successful insertion as visualized, for example, by acquisition of immunoreactivity to an antibody immunologically specific for the polypeptide encoded by AID-associated SNV nucleic acid and, therefore, facilitates screening/selection of ES cells with the desired genotype.

As used herein, a knock-in animal is one in which the endogenous murine gene, for example, has been replaced with human AID-associated SNV containing gene of the invention. Such knock-in animals provide an ideal model system for studying the development of pAID.

As used herein, the expression of a AID-associated SNV containing nucleic acid, fragment thereof, or an AID-associated SNV fusion protein can be targeted in a “tissue specific manner” or “cell type specific manner” using a vector in which nucleic acid sequences encoding all or a portion of an AID-associated SNV are operably linked to regulatory sequences (e.g., promoters and/or enhancers) that direct expression of the encoded protein in a particular tissue or cell type. Such regulatory elements may be used to advantage for both in vitro and in vivo applications. Promoters for directing tissue specific proteins are well known in the art and described herein.

The nucleic acid sequence encoding the AID-associated SNV of the invention may be operably linked to a variety of different promoter sequences for expression in transgenic animals. Such promoters include, but are not limited to a prion gene promoter such as hamster and mouse Prion promoter (MoPrP), described in U.S. Pat. No. 5,877,399 and in Borchelt et al., Genet. Anal. 13(6) (1996) pages 159-163; a rat neuronal specific enolase promoter, described in U.S. Pat. Nos. 5,612,486, and 5,387,742; a platelet-derived growth factor B gene promoter, described in U.S. Pat. No. 5,811,633; a brain specific dystrophin promoter, described in U.S. Pat. No. 5,849,999; a Thy-1 promoter; a PGK promoter; and a CMV promoter for the expression of transgenes in airway smooth muscle cells.

Methods of use for the transgenic mice of the invention are also provided herein. Transgenic mice into which a nucleic acid containing the AID-associated SNV or its encoded protein have been introduced are useful, for example, to develop screening methods to screen therapeutic agents to identify those capable of modulating the development of AID.

Pharmaceuticals and Further Methods of Treatment

The elucidation of the role played by the AID associated SNVs described herein in modulating the AID phenotypes may facilitate the development of further pharmaceutical compositions useful for treatment and diagnosis of AIDs including pAIDs. Such information may also enable new uses of existing pharmaceutical agents in combination for the treatment of AID. These compositions may comprise, in addition to one of the above substances, a pharmaceutically acceptable excipient, carrier, buffer, stabilizer or other materials well known to those skilled in the art. Such materials should be non-toxic and should not interfere with the efficacy of the active ingredient. The precise nature of the carrier or other material may depend on the route of administration, e.g. oral, intravenous, cutaneous or subcutaneous, nasal, aerosolized, intramuscular, and intraperitoneal routes.

The invention includes a method of treating AID in a mammal. Preferably, the mammal is a human. An exemplary method entails administering to the mammal a pharmaceutically effective amount of AID siRNA. The siRNA may inhibit the expression of AID associated mRNA.

Specific siRNA preparations directed at inhibiting the expression of AID mRNA, as well as delivery methods are provided as a novel therapy to treat AID. SiRNA oligonucleotides directed to AID nucleic acids specifically hybridize with nucleic acids encoding AID genes and interfere with AID gene expression. The siRNA can be delivered to a patient in vivo either systemically or locally with carriers, as discussed below. The compositions of the invention may be used alone or in combination with other agents or genes encoding proteins to augment the efficacy of the compositions.

A “membrane permeant peptide sequence” refers to a peptide sequence able to facilitate penetration and entry of the AID inhibitor across the cell membrane. Exemplary peptides include without limitation, the signal sequence from Karposi fibroblast growth factor exemplified herein, the HIV tat peptide (Vives et al., J Biol. Chem., 272:16010-16017, 1997), Nontoxic membrane translocation peptide from protamine (Park et al., FASEB J. 19(11):1555-7, 2005), CHARIOT® delivery reagent (Active Motif; U.S. Pat. No. 6,841,535) and the antimicrobial peptide Buforin 2.

In one embodiment of the invention siRNAs are delivered for therapeutic benefit. There are several ways to administer the siRNA of the invention in vivo to treat AID including, but not limited to, naked siRNA delivery, siRNA conjugation and delivery, liposome carrier-mediated delivery, polymer carrier delivery, nanoparticle compositions, plasmid-based methods, and the use of viruses.

siRNA composition of the invention can comprise a delivery vehicle, including liposomes, for administration to a subject, carriers and diluents and their salts, and/or can be present in pharmaceutically acceptable formulations. This can be necessary to allow the siRNA to cross the cell membrane and escape degradation. Methods for the delivery of nucleic acid molecules are described in Akhtar et al., 1992, Trends Cell Bio., 2, 139; Delivery Strategies for Antisense Oligonucleotide Therapeutics, ed. Akhtar, 1995, Maurer et al., 1999, Mol. Membr. Biol., 16, 129-140; Hofland and Huang, 1999, Handb. Exp. Pharmacol., 137, 165-192; and Lee et al., 2000, ACS Symp. Ser., 752, 184-192; Beigelman et al., U.S. Pat. No. 6,395,713 and Sullivan et al., PCT WO 94/02595 further describe the general methods for delivery of nucleic acid molecules. These protocols can be utilized for the delivery of virtually any nucleic acid molecule.

The frequency of administration of the siRNA to a patient will also vary depending on several factors including, but not limited to, the type and severity of the AID to be treated, the route of administration, the age and overall health of the individual, the nature of the siRNA, and the like. It is contemplated that the frequency of administration of the siRNA to the patient may vary from about once every few months to about once a month, to about once a week, to about once per day, to about several times daily.

Pharmaceutical compositions that are useful in the methods of the invention may be administered systemically in parenteral, oral solid and liquid formulations, ophthalmic, suppository, aerosol, topical or other similar formulations. In addition to the appropriate siRNA, these pharmaceutical compositions may contain pharmaceutically-acceptable carriers and other ingredients known to enhance and facilitate drug administration. Thus such compositions may optionally contain other components, such as adjuvants, e.g., aqueous suspensions of aluminum and magnesium hydroxides, and/or other pharmaceutically acceptable carriers, such as saline. Other possible formulations, such as nanoparticles, liposomes, resealed erythrocytes, and immunologically based systems may also be used to administer the appropriate siRNA to a patient according to the methods of the invention. The use of nanoparticles to deliver siRNAs, as well as cell membrane permeable peptide carriers that can be used are described in Crombez et al., Biochemical Society Transactions v35:p44 (2007).

The following examples are provided to illustrate certain embodiments of the invention. They are not intended to limit the invention in any way.

Example I Identification of Genetic Markers for pAID

Autoimmune diseases affect 7-10% of individuals living in the Western Hemisphere¹, and represent a significant cause of chronic morbidity and disability. High rates of familial clustering and comorbidity across autoimmune diseases suggest that genetic predisposition underlies disease susceptibility. GWAS and immune-focused fine-mapping studies of autoimmune thyroiditis (AITD)², psoriasis (PSOR)³, juvenile idiopathic arthritis (JIA)⁴, primary biliary cirrhosis (PBC)⁵, primary sclerosing cholangitis (PSC)⁶, rheumatoid arthritis (RA)⁷, celiac disease (CEL)⁸, inflammatory bowel disease (IBD, which includes Crohn's Disease (CD) and ulcerative colitis (UC)⁹), and multiple sclerosis (MS)^(10,11) have identified hundreds of autoimmune disease-associated single-nucleotide polymorphisms (SNVs) across the genome¹²⁻¹⁴. SNV associations in certain pan-autoimmune loci, such as PTPN22 c.1858C>T (rs2476601), are evident in independent GWAS across multiple autoimmune diseases¹⁵⁻¹⁸, while others have been uncovered through large-scale meta-analyses (e.g. CEL/RA, T1D/CD) or through lookup of known loci from one disease in another (e.g. SLE)¹⁹. These studies demonstrate that over half of genome wide significant (GWS) autoimmune disease associations are shared by at least two distinct autoimmune diseases^(20,21). However, the degree to which common, shared genetic variations may similarly affect the risk of different pediatric age-of-onset autoimmune diseases (pAIDs) and whether these effects are heterogeneous have not been systematically examined at the genotype level across multiple diseases simultaneously.

To identify shared genetic etiologies underlying pAIDs and to illustrate how such associations may jointly or disparately affect pAID susceptibility, we performed a modified heterogeneity sensitive GWAS (hsGWAS) across ten common pAIDs. We modeled pAIDs as a heterogeneous phenotype, assigning each of the ten pAIDs as a disease subtype. By combining disease model-search²³, regional imputation, and disease model-specific association testing, we can maximize the power to identify risk variants shared across multiple autoimmune diseases in the context of phenotypic and genetic heterogeneity. Our study, including over 16,000 case-control individuals all genotyped on comparable platforms at The Children's Hospital of Philadelphia (CHOP), represents the largest pAID genetic association study performed to date.

Over hundred autoimmune disease loci have been reported in multiple independent GWAS studies of over a dozen pAIDs. Consistent with clinical observations that some pAIDs, such as THY, CEL and T1D, exhibit high rates of disease comorbidity, while others, such as CD and UC, have clear familial clustering, about half of all the GWS associations reported have been independently reported in at least one other autoimmune disease.

To address true genetic sharing across different autoimmune diseases, unbiased genome-wide approaches are needed as meta-analyses have mostly focused on known or candidate loci. However, a few studies have utilized genetic correlations to boost study power of genetic discovery and simultaneously investigated the genetic overlap across multiple autoimmune diseases affecting adults⁶⁰⁻⁶⁵, similar to what we report in the present analysis for pAIDs. Indeed, given that most pAIDs are relatively rare, combining multiple diseases with expected genetic overlap to increase sample size, presents an intuitive approach addressing both discovery and replication, and far better powered than by directly merging cases in a classic GWAS.

Results Shared Genetic Risk Associations Across Ten Pediatric Autoimmune Diseases

We performed whole-genome imputation on a combined cohort of over 6,035 pediatric cases across 10 clinically-distinct pAIDs (Supplementary Table 1a) and 10,718 population-based control subjects without prior history of autoimmune/immune-mediated disorders. We performed whole chromosome phasing and used the 1,000 Genomes Project Phase I Integrated cosmopolitan reference panel (1KGP-RP) for imputation as previously described (SHAPEIT and IMPUTE2)^(22,23). Only individuals of self-reported European ancestry, and confirmed by Principal Component Analysis (FIG. 1E), were included (See Methods). Rare (minor allele frequency [MAF]<1%) and poorly-imputed (INFO<0.8) SNVs were removed, leaving a total of 7,347,414 variants.

Whole-genome case-control association testing was performed using case samples from each of the ten pAID cases and the shared controls, additive logistic regression was applied using SNPTESTv2.5²⁴. There was no evidence of genomic inflation. To identify shared pAID association loci, we performed an inverse chi-square meta-analysis, accounting for sample size variation and the use of a shared control across the ten pAIDs²⁵. We identified 27 linkage disequilibrium (LD)-independent loci, consisting of associated SNPs with r²>0.05 within a 1 Mb window where at least one lead SNP reached a conventionally-defined GWS threshold (P<5×10⁻⁸); See FIG. 1C and FIG. 1F. An additional 19 loci reached a marginally-significant (GWM) threshold at or below P_(META)<1×10⁻⁶, among which twelve map to previously-reported and seven to putatively novel autoimmune loci (FIG. 1 and Supplementary Table 2a).

We identified five novel GWS loci, including CD40LG (P_(META)<8.38×10⁻¹¹), LPHN2 (P_(META)<8.38×10⁻¹¹), TNM3 (P_(META)<8.38×10⁻¹¹), ANKRD30A (P_(META)<8.38×10⁻¹¹), and ADCY7 (P_(META)<5.99×10⁻⁹). For each lead association locus, we identified the corresponding combination of pAIDs contributing to the association signal, by enumerating all 1,023 unique disease combinations (e.g., one-disease: T1D, two diseases: T1D and SLE, or four diseases: UC, CD, CEL and SLE) and performing association testing to identify the disease combination that yields the maximum logistic regression Z-score (see Methods)²⁶. With the exception of ANKRD30A, the remaining four putatively novel loci were jointly associated with at least two or more pAIDs; for example, CD40LG was shared by CEL, CD, and UC (FIG. 1 and Table 1). Among the 27 GWS lead SNPs, 22 were previously-reported as GWS for at least one of the associated pAIDs (i.e., the corresponding adult phenotypes) identified by our analysis (Supplementary Table 1b)^(12,27). The most widely shared locus, chr4q27: rs62324212 mapping to an intronic SNP in IL21 antisense RNA/and residing just upstream of IL21, was shared across all 10 diseases, three of which are novel (THY|AS|CVID). Among the previously known GWS loci in adult-onset or generalized autoimmune disease, we identified at least one novel pediatric age of onset autoimmune disease association for over 50% of them (Table 2d and Table 2c).

A number of the pAIDs are significantly associated with disease-specific signals mapping to or near the locus encoding HLA-DRB1. However, even the two most significant, LD-independent variants associated with T1D and JIA, respectively, were disease-specific (FIG. 3C), suggesting that the variants associated with a given disease are distinct. Although some of these associated signals are shared by at least one other autoimmune diseases, in no instance is a single signal associated with any of the diseases shared across all other diseases, further underscoring the complexity of signal sharing across the MHC (FIG. 3D).

Disease-Specific and Cross-Autoimmune Replication Support for the pAID Associated Loci

We performed in silico analysis to test if the reported associations can be replicated in an independent dataset. We observed nominally significant replication support for four of the five putatively novel GWS loci, including three instances of disease-specific replication (Supplementary Table 1d). Among the replicated loci, chrXq26.3 (rs2807264) mapping within 70 Kb upstream of CD40LG, is notable, as we observe disease-specific replication in both UC (P<4.66×10⁻⁵) and CD (P<5.81×10⁴), as well as cross-autoimmune replication in AS (P<9.54×10⁻³). Although rs2807264 was not identified in our analysis as being associated with pediatric AS, it has been well-documented that adult-onset AS may be biologically a different disease with independent genetic etiologies.^(28,29) A third disease-specific replication (P<5.99×10⁻⁶) was identified in CD for the chr16q12.1 (rs77150043) signal mapping to an intronic position in ADCY7. This latter instance and the replication of the CD40LG locus in UC were both significant, even following a very conservative Bonferonni adjustment for 156 tests (P<3.21×10⁴). A nominally significant pan-autoimmune replication signal (P<1.69×10⁻²) was also observed at chr1p31.1 (rs2066363) near LPHN2 in UC, and replication signal (P<3.65×10⁻³) was also observed at the chr4q35.1 locus (rs77150043) in PS (Supplementary Table 1d and Table 2e).

Sharing of pAID-Associated SNPs and Bidirectional Effects of Some SNPs on Disease-Specific Risk

Of the 27 GWS loci, 81% (22) showed evidence of being shared among multiple pAIDs. These map to 77 unique SNP-pAID combinations, 44 of which have been previously reported at or near GWS (P<1×10⁻⁶), while 33 represent potentially novel disease association signals (Table 1 and Supplementary Table 1). While PTPN22 c.1858C>T (rs2476601) increases the risk for T1D, the variant is protective for CD^(17,30-32). We identified eight other instances (P<0.05) where the risk allele shared by the model pAID combination was associated with protection against another pAID (FIG. 2A and FIG. 7A).

TABLE 1 Twenty-seven independent loci reaching GWS (P_(META) < 5 × 10⁻⁸) after adjusting for the use of shared controls using an inverse chi-square meta-analysis across the pAIDs. CHR POS(Mb) SNP REGION GENE A1 MAF P_(META) Known_P* pAIDs 1 67.7 rs11580078 1p31.3 IL23R G 0.43 8.4E−11  1.0E−146 CD# 1 82.2 rs2066363 1p31.1 LPHN2 C 0.34 8.4E−11 novel CVID|JIA 1 114.3 rs6679677 1p13.2 PTPN22 A 0.09 8.4E−11 1.1E−88 THY#|PS|T1D#|JIA# 2 234.2 rs36001488 2q37.1 ATG16L1 C 0.48 8.4E−11 1.0E−12 PS|CD# 3 49.6 rs4625 3p21.31 DAG1 G 0.31 8.4E−11 1.0E−47 PS#|CEL|UC#|CD# 4 123.6 rs62324212 4q27 IL21 A 0.42 2.6E−08 1.0E−09 THY|AS|CEL#|CVID| UC#|T1D#|JIA#|CD# 4 183.7 rs7660520 4q35.1 TNM3 A 0.26 8.4E−11 novel THY|AS|CEL|SLE| CVID|JIA 5 40.5 rs7725052 5p13.1 PTGER4 C 0.43 8.4E−11 1.4E−10 CD# 5 55.4 rs7731626 5q11.2 ANKRD55 A 0.39 1.4E−10 2.7E−11 JIA|CD# 5 131.8 rs11741255 5q31.1 IL5 A 0.42 1.6E−09 1.4E−52 PS#|CEL|CD# 5 158.8 rs755374 5q33.3 IL12B T 0.32 2.3E−10 1.4E−42 AS#|CEL|UC#|CD# 9 117.6 rs4246905 9q32 TNFSF15 T 0.28 9.5E−09 1.2E−17 UC#|CD# 9 139.3 rs11145763 9q34.3 CARD9 C 0.40 3.3E−08 1.0E−06 AS#|UC#|CD# 10 6.1 rs706778 10p15.1 IL2RA T 0.41 6.3E−09 1.7E−12 THY|AS|PS#|CEL| T1D#|JIA# 10 37.6 rs7100025 10p11.21 ANKRD30A G 0.34 8.4E−11 novel JIA 10 64.4 rs10822050 10q21.2 ZNF365 C 0.39 8.4E−11 5.0E−17 SLE|CD# 10 81.0 rs1250563 10q22.3 ZMIZ1 C 0.29 1.3E−08 1.1E−30 PS#|CD# 10 101.3 rs1332099 10q24.2 NKX2-3 T 0.46 9.1E−11 1.0E−54 UC#|CD# 11 2.2 rs17885785 11p15.5 INS T 0.20 8.4E−11 4.4E−48 T1D# 12 40.8 rs17466626 12q12 LRRK2 G 0.02 3.2E−10 3.0E−10 AS|CD# 12 56.4 rs1689510 12q13.2 SUOX C 0.31 4.0E−09 1.1E−10 PS#|TlD# 15 67.5 rs72743477 15q22.33 SMAD3 G 0.21 8.4E−11 2.7E−19 AS|UC|CD# 16 28.3 rs12598357 16p11.2 SBK1 G 0.39 4.4E−09 1.0E−08 THY|AS#|PS|CEL| UC|CD# 16 50.3 rs77150043 16q12.1 ADCY7 T 0.23 6.0E−09 novel PS|CD 16 50.7 rs117372389 16q12.1 NOD2 T 0.02 8.4E−11 2.9E−69 CD# 21 40.5 rs2836882 21q22.2 PSMG1 A 0.27 4.8E−08 2.8E−14 UC#|CD# 23 135.7 rs2807264 Xq26.3 CD40LG C 0.21 1.3E−08 novel CEL|UC|CD CHR: chromosome; SNP: dbSNP rsID; POS (Mb): position in hg19; REGION: Cytogenetic band; A1: alternative allele; MAF: minor allele frequency (controls); GENE: candidate gene name (HNGC); P_(META): Meta-analysis P-value; Known-P*: Lowest P-value from published association studies; “novel” denotes new loci (bolded) reaching GWS for the first time in the present study; pAIDs: pAIDs associated with the locus; (#) denotes if the SNP-disease associated has been previously reported.

To integrate our results with experimental and predictive biological data, we curated four categories of SNP annotations: 1) functional: variants that are exonic or impact transcription, miRNA targets or tag copy-number polymorphic regions; 2) regulatory: transcription factor (TF)-binding sites and DNase hypersensitivity sites or eQTLs SNPs; 3) conserved: variants with evolutionarily-constrained positions or CpG islands; or 4) prior literature support: gene or locus previously reported to be associated with autoimmune diseases or immune function. Indeed, 100% of the GWS lead SNPs or their nearby LD proxies (r²>0.8 based on 1KGP-RP within 500 Kb up- or downstream) belong to one or more of these categories (FIG. 3A). Nevertheless, the majority of the 27 GWS SNPs do not confer transcriptional consequences (51% are intronic variants, 28% are intergenic or up/downstream gene variants), suggesting that many of these SNPs are either tagging the true causal variants or impact disease risk through regulatory and/or epigenetic mechanisms (FIG. 3B).

To determine if the set of pAID-associated SNPs were enriched for specific annotation categories, we compared their annotation percentage with that of 10,000 simulated sets of SNPs with MAF>0.01 drawn from the 1KGP-RP, for each category. We found that pAID-associated SNPs are enriched for CpG islands (P_(perm)<1.0×10⁻⁴), transcription-factor binding sites (P_(perm)<3.4×10⁻³), and miRNA binding sites (P_(perm)<1.0×10⁻⁴), among other findings of biological disease relevance (FIGS. 1H and 1I).

Candidate pAID Genes Share Expression Profiles Across Immune Cell Types and Tissues

Recent studies show that gene-based association testing (GBAT) may boost the power of genetic discovery³³⁻³⁵. We performed GBAT (VEGAS³³), using genome-wide summary-level P_(META)-values. We identified 182 significant pAID-associated genes (simulation-based P_(sim)<2.80×10⁻⁶), based on a Bonferonni adjustment for ˜17,500 protein-coding genes in the genome (Table 3a). To illustrate the biological relevance of this gene set, we examined their transcript levels in a human gene expression microarray dataset consisting of 12,000 genes and 126 tissue/cell types³⁶. The distribution of pAID-associated gene expression was notably higher across immune (ES-I, =4.05) versus non-immune (ES-NI=2.10) tissues or cell types, based on a one-tailed Wilcoxon rank-sum test (P<1.66×10⁻¹⁰). When all extended MHC genes were excluded, the average expression of pAID associated genes remained significantly higher (P<1.27×10⁻⁷) across immune (ES-I=1.043) versus non-immune (ES-NI=0.648) cells/tissues. The immune-specific enrichment of pAID-associated gene transcripts was comparable to those observed in adult cohorts¹²; comparatively, schizophrenia-associated genes showed no such enrichment (FIG. 4A). Similar results were observed using the Kolmogorov-Smirnov (KS) test (FIG. 5D).

We examined the expression of pAID genes across a whole-transcriptome dataset comprising over 200 murine immune cell types isolated by flow cytometry (ImmGen³⁷; see Methods and Table 3c). Genes associated with pAIDs demonstrated differential expression across immune cell types (FIG. 5E), and were more highly expressed as compared to genes associated with non-immune traits, similar to results observed from human tissue data (FIG. 4B). As the expression levels of these “pleiotropic” genes varied diversely across immune cell types, we performed agglomerative hierarchical clustering to identify sets of genes sharing similar profiles. Genes that belong to the same cluster (hence sharing similar expression profiles) were found to be enriched for association with a specific or multiple autoimmune diseases (see annotated clusters in FIG. 4C). For example, cluster 1 genes, including ICAM1, CD40, JAK2, TYK2 and IL12B, with known roles in immune effector cell activation and proliferation, were enriched for association with PSC, UC, and associated with both diseases (P<6.82×10⁻⁴; one-tailed Fisher's Exact test), and the expression of these genes was highest in a small subset of CD11b⁺ lymphoid dendritic cells. These findings are consistent with the clinical observation that as many as 80% of patients diagnosed with PSC have been diagnosed with UC, and the risk of PSC is approximately 600-fold higher in patients with UC.^(38,39) Cluster 2 genes include a number of cytokines and cytokine-response factors, including IL19, IL20, STAT5A, and IL2RA, which regulate effector T-cell activation, differentiation, and proliferation all of which were more broadly expressed, across mature natural killer (NK), NK-T and T cells as well as neutrophils. This cluster of genes is enriched for association with MS (P<9.8×10⁴), marginally with CEL (P<0.062), and both diseases (P<3.41×10⁴). Genes encoding nucleic acid binding proteins, including ILF3, CENPO, MEM, and NCOA3, are enriched in cluster 3. Genes in this cluster are jointly associated with SLE and PS (P<0.03), which is consistent with experimental and clinical data demonstrating that early defects in B^(40,41) and T-cell⁴²⁻⁴⁴ clonal selection may play an important role in the etiology of these diseases, respectively.

Quantification of Genetic Risk Factor Sharing Across pAIDs

We developed a novel method to specifically examine genome-wide, pair-wise association signal sharing (GPS test) across the pAIDs (See Methods). Only data from the genotyped pAID cohort were used for this analysis. After Bonferroni adjustment for 45 pairwise combinations, the GPS test identified evidence of sharing between a number of pAID pairs noted in prior reports on autoimmune disease, including T1D-CEL (P_(gps)<3.44×10⁻⁵), T1D-THY (P_(gps)<2.03×10⁻³) UC-CD (P_(gps)<2.36×10⁻³), and AS-PS (P_(gps)<8.15×10⁻³). We also identified a strong GPS score for JIA-CVID_(gp)s<6.88×10⁻⁵). Interestingly, the correlations between JIA-CVID (P_(gps)<7.30×10⁻⁵) and UC-CD (P_(gps)<7.32×10^(−a)) were more significant following the exclusion of markers within the MHC region (FIG. 7B).

Finally, we examined evidence of sharing across the full range of autoimmune diseases using the immunobase (www.immunobase.org)²⁷. We identified significant associations between UC-CD (P<2.15×10⁻⁴) and JIA-CVID (P<1.44×10⁻⁶), along with a number of novel pairwise relationships that include autoimmune diseases other than the ten cohorts unique to this study, such as that between SJO-SS (P<1.30×10⁻²⁸) and PBC-SJO (P<3.86×10⁻¹²). We plotted those relationships that were significant following a Bonferroni adjustment for 153 pairwise tests using an undirected weighted network (FIG. 5B and Table 4). Collectively, these results support genetic sharing between the various autoimmune diseases and allow for further refinement of the shared signals potentially enabling targeted therapeutic interventions to be applied at multiple levels, such as the CD40L/CD40, JAK-STAT and the TH₁-TH₂/TH₁₇-interleukin signaling pathways.

Discussion

A major goal of this study was to identify shared genetic etiologies across pAIDs and illustrate how they jointly and disparately affect pAID susceptibility.

Knowledge of shared genetic etiologies may help pinpoint common therapeutic mechanisms, especially since certain pAIDs (e.g., THY, CEL and T1D) exhibit high rates of comorbidity and concordance in twins with others (e.g., CD and UC) being clustered in families^(9,19,45,46). Thus, among our primary objectives is to identify those patients who share genetic target(s) and identify therapeutic agents which may impact the activity of such genetic targets independent of patient disease classification and thereby develop new therapies, either de novo or through drug repositioning and develop them through studies on mutation positive patients. The goal is to identify therapeutic drug combinations which may act synergistically to alleviate symptoms of disease or inhibit progression to pAID.

Of the 27 pAID GWS association loci identified, 81% were shared by at least two pAIDs (Table 1 and Supplementary Table 1). Moreover, five of the 27 loci are novel signals not previously reported at GWS levels in association with autoimmune diseases, including chr1p31.1 (rs2066363) mapping near LPHN2, a gene that encodes a member of the latrophilin subfamily of G-protein coupled receptors that regulates exocytosis. While this signal associated with JIA and CVID, a microsatellite study of PBC in a Japanese cohort had identified an association signal to a 100 Kb region enclosing LPHN2.⁴⁷ Nominally significant replication support at this locus was identified in the adult UC cohort from the IBD consortium. Both JIA and CVID are among the six pAIDs (THY|AS|CEL|SLE|CVID|JIA) associated with the chr4q35.1 locus (rs7660520), which resides just downstream of TNM3 The observed association with a broad range of pAIDs may be related to eQTL signals in TNM3 SNPs that correlate with serum eosinophil counts⁴⁸ and IgG glycosylation rates, the latter reported by a landmark study showing a pleiotropic role for IgG glycosylation-associated SNPs in autoimmune disease risk susceptibility.⁴⁹ The third novel association was identified near chr10p11.21 (rs7100025) mapping to a transcription-factor ANKRD30A, a gene encoding an antigen recognized by CD8+ T-cell clones⁵⁰. The fourth signal associated with the inflammatory disease PS and CD near chr16q12.1 (rs77150043). This intronic SNP in ADCY7, encodes a member of the adenylate cyclase (AC) enzyme family and is strongly expressed in peripheral leukocytes, spleen, thymus, and lung tissues⁵¹ and supported by mouse data⁵². The fifth novel signal, rs34030418, mapping near CD40LG and associating with CEL|UC|CD, is the ligand of a prominent TNF superfamily receptor CD40^(53,54). CD40 ligand is a particularly compelling candidate as the locus encoding the CD40 receptor is an established GWAS locus in RA and MS, has been functionally studied in cell culture and animal models, and was the focus of a recent large-scale RA drug-screening effort⁵⁵.

A set of GWS candidate SNPs are enriched for miRNA and transcription factor (TF) binding sites. We performed a gene-set enrichment analysis⁵⁶ using GBAT, identifying 39 significant (P_(BH)<0.05) miRNAs, including as top candidates two well-known miRNA families miR-22 and miR-135a (Table 5a). The latter is shown to target IRS2, a regulator of insulin signaling and glucose uptake in a model systems⁵⁷. Our candidate genes are enriched for targets of dozens of TFs, with the most prominent being SP1 (P_(BH)<2.30×10⁻¹²), NFAT (P_(BH)<8.54×10⁻⁹), and NFKB (P_(BH)<1.03×10⁻⁸). See Table 5b.

Using GBAT, we identified strong enrichment for proteins that act in cytokine signaling, antigen processing and presentation, T-cell activation, JAK-STAT activation, and Th₁, Th₂, and Th₁₇-associated cytokine signaling using DAVID⁵⁸, GSEA³⁶, IPA⁵⁹, and Pathway Commons⁶⁰, among others (Table 6). Of these, JAK2 signaling is particularly compelling (P_(BH)<6.93×10⁻⁵; FIG. 6B) consistent the enrichment of known PPIs (P_(STRING)<1×10⁻²⁰) (FIG. 6). We also uncovered evidence supporting shared genetic susceptibility for disease pairs that not yet been well-established (e.g. JIA|CVID). The association between JIA and CVID is noteworthy, given that CVID actually represent a group of complex immunodeficiencies rather than a classic autoimmune disease. When we examined the overlap between CVID and all other pAIDs using both the GPS (P_(adj)<3.10×10^(−s)) and LPS (P_(adj)<1.47×10⁻⁸) network analysis tests, we consistently observed overrepresentation of interaction between CVID and JIA (FIG. 5 and FIG. 7B). Our results show that over 70% (19) of the 27 GWS loci we identified were shared by at least three autoimmune diseases (Table 1), including both previously-reported (e.g., IL2RA [6], IL12B [4]) and novel signals (e.g., TNM3 [6], CD40LG [3]). Moreover, using TGSEA, we not only highlighted the expected enrichment of genes associated with CEL and SLE in Tγ_(δ), T_(CD4) and NK-T cells, but also identified interesting joint enrichment of genes associated with PSC and UC in a set of mature dendritic cells (FIG. 4C).

Many of the shared risk factors in pAIDs impact genes that encode for proteins which are established therapeutic targets, for example the anti-CD40L and anti-CD40 antibodies^(54,55) and a number of the genes identified here have diverse biological effects and are currently in clinical development. Consequently, drug repurposing approaches may present feasible options in pAIDs, where these gene networks and pathways will be targeted in an expedited manner.

Methods

Affected subjects and controls were identified either directly as described in prior studies^(61,62, 63,64,65,66,67,68,69,70) or from de-identified samples and associated electronic medical records (EMRs) in the genomics biorepository at The Children's Hospital of Philadelphia (CHOP). The predominant majority (>80%) of the included cases for IBD, T1D and CVID have been described in previous publications. Details of each study population are outlined below. EMR searches were conducted with previously described algorithms based on phenotype mapping established using phenome-wide association study (PheWAS) ICD-9 code mapping tables^(61,62,63,70) in consultation with qualified physician specialists for each disease cohort. All DNA samples were assessed for quality control (QC) and genotyped on the Illumina HumanHap550 or HumanHap610 platform at the Center for Applied Genomics (CAG) at CHOP. Note that the patient counts below refer to the total recruited sample size from which we excluded non-qualified samples or genotypes that did not pass QC criteria required for inclusion in the genetic analysis (for example, because of relatedness or poor genotyping rate). The IBD cohort comprised 2,796 individuals between the ages of 2 and 17, of European ancestry, and with biopsy-proven disease, including 1,931 with CD and 865 with UC and excluding all patients with unclassified IBD. Affected individuals were recruited from multiple centers from four geographically discrete countries and were diagnosed before their 19th birthday according to standard IBD diagnostic criteria, as previously reported^(63,65). The T1D cohort consisted of 1,120 subjects from nuclear family trios (one affected child and two parents), including 267 independent Canadian T1D patients collected in pediatric diabetes clinics in Montreal, Toronto, Ottawa and Winnipeg and 203 T1D patients recruited at CHOP since September 2006. All patients were Caucasian by self-report and between 3 and 17 years of age, with a median age at onset of 7.9 years. All patients had been treated with insulin since diagnosis. Disease diagnosis was based on these clinical criteria, rather than on any laboratory tests. The JIA cohort was recruited in the United States, Australia and Norway and comprised a total of 1,123 patients with onset of arthritis at less than 16 years of age. JIA diagnosis and JIA subtype were determined according to the International League of Associations for Rheumatology (ILAR) revised criteria⁷¹ and confirmed using the JIA Calculator⁷² (http://www.ra-researCh.org/JIAcalc/), an algorithm-based tool adapted from the ILAR criteria. Prior to standard QC procedures and exclusion of non-European ancestry, the JIA cohort comprised 464 subjects of self-reported European ancestry from Texas Scottish Rite Hospital for Children (Dallas, Tex., USA) and the Children's Mercy Hospitals and Clinics (Kansas City, Mo., USA); 196 subjects from CHOP; 221 subjects from the Murdoch Children's Research Institute (Royal Children's Hospital, Melbourne, Australia); and 504 subjects from Oslo University Hospital (Oslo, Norway). The CVID study population consisted of 223 patients from Mount Sinai School of Medicine (MSSM; New York, N.Y., USA), 76 patients from University of Oxford, (London, England), 47 patients from CHOP, and 27 patients from University of South Florida (USF; Tampa, Fla., USA). The diagnosis in each case was validated against the ESID-PAGID diagnostic criteria, as previously described⁷³. Although the diagnosis of CVID is most commonly made in young adults (ages 20-40), all of the CHOP and USF subjects had pediatric-age-of-onset disease, whereas the majority of the subjects from MSSM and Oxford had onset in young adulthood. We note that as the number of individuals with adult-onset CVID is so small (less than 5% of all cases presented) and all ten diseases studied here can present with pediatric age of onset, we elected to refer to the cohort material as pAID. The balance of the pediatric subjects' (THY, AS, PSOR, CEL and SLE; a full list of phenotype abbreviations is provided in the Tables) samples were derived from our biorepository at CHOP, which includes more than 50,000 pediatric patients recruited and enrolled by CAG at CHOP (The Tables include details of genotyped subjects within the CAG pediatric biobank). These individuals were confirmed for diagnosis of THY, SPA, PSOR, CEL and SLE in the age range of 1-17 years at the time of diagnosis and were required to fulfill the clinical criteria for these respective disorders, as confirmed by a specialist. Only patients that upon EMR search were confirmed to have at least two or more in-person visits, at least one of which was with the specified ICD-9 diagnosis code(s), were pursued for clinical confirmation. We used ICD-9 codes previously identified and used for PheWASs or EMR-based GWASs and agreed upon by board-certified physicians^(62,63). Age- and gender-matched control subjects were identified from the CHOP-CAG biobank and selected by exclusion of any patient with any ICD-9 codes for disorders of autoimmunity or immunodeficiency⁶¹ (http://icd9.chrisendres/). Research ethics boards of CHOP and other collaborating centers approved this study, and written informed consent was obtained from all subjects (or their legal guardians). Genomic DNA extraction and sample QC before and after genotyping were performed using standard methods as described previously⁶⁴. All samples were genotyped at CAG on HumanHap550 and 610 BeadChip arrays (Illumina, CA). To minimize confounding due to population stratification, we included only individuals of European ancestry (as determined by both self-reported ancestry and principal-component analysis (PCA)) for the present study. Details of the PCA are provided below. Genotyping, Imputation, Association Testing and QC. Disease-Specific QC. We merged the genotyping results from each disease-specific cohort with data from the shared controls before extracting the genotyping results from SNPs common to both Infinium HumanHap550 and 610 BeadChip array platforms and performing genotyping QC. SNPs with a low genotyping rate (<95%) or low MAF (<0.01) or those significantly departing from the expected Hardy-Weinberg equilibrium (HWE; P<1×10⁻⁶) were excluded. Samples with low overall genotyping call rates (<95%) or determined to be of outliers of European ancestry by PCA (>6.0 s.d. as identified by EIGENSTRAT⁷⁴) were removed. In addition, one of each pair of related individuals as determined by identity-by-state analysis (PI_HAT>0.1875) was excluded, with cases preferentially retained where possible. Merged-Cohort QC. To prepare for whole-genome imputation across the entire study cohort, we combined case samples across the 10 pAIDs with the shared control samples. We repeated the genotyping and sample QC with the same criteria as described above, leaving a final set of ˜486,000 common SNPs passing individual-cohort and merged-cohort QC. We again performed identity-by-state analysis and removed related samples (in order to remove related subjects that may have been recruited for different disease studies). We also repeated the PCA and removed population outliers. The final cohort, after the application of all QC metrics mentioned above, included a total of 6,035 patients representing ten pAIDs and 10,718 population-matched controls. Note that because of the merged QC, compared with the sum of all ten disease-specific GWASs, the final case and control counts in the merged cohort were smaller than the “sum of all cases and controls” (Supplementary Table 1a). In addition, to avoid the potential for confounding due to the presence of duplicated samples, we assigned individuals fitting the diagnostic criteria for two or more pAIDs to whichever disease cohort had the smaller (or smallest) sample size. No subject was included twice. A total of 160 subjects in the study cohort fulfilled criteria for two or more diseases but were counted only once in our reported total of 6,035 unique subjects. Whole-Genome Phasing and Imputation. We used SHAPEIT⁷⁵ for whole-chromosome prephasing and IMPUTE2 (ref. 76) for imputation to the 1KGP-RP (https://mathgen.stats.ox.ac.uk/impute/impute v2.html, June 2014 haplotype release). For both, we used parameters suggested by the developers of the software and described elsewhere^(75,76,77). Imputation was done for each 5-Mb regional chunk across the genome, and data were subsequently merged for association testing. Prior to imputation, all SNPs were filtered using the criteria described above. To verify the imputation accuracy, we validated randomly selected SNPs that reached a nominally significant P value after imputation. Because commercially designed genotyping probes were not readily available, we performed Sanger sequencing by designing primers to amplify and sequence the 200-bp region around the imputed SNP markers for two separate 96-well plates. We manually visualized and examined sequences and chromatograms using SeqTrace⁷⁸. Results from this are presented in Supplementary Table 1e, showing >99% mean imputation accuracy. In addition, a subset of the IBD and CVID subjects were subsequently genotyped on the Immunochip (Illumina) platform. We compared the genotype concordance of all pAID GWAS imputed SNPs that were directly genotyped on the Immunochip after performing sample and marker QC as described above. Results are shown in Supplementary Table 1f. Disease-Specific Association Testing. We performed whole-genome association testing using post-imputation genotype probabilities with the software SNPTEST (v2.5)²⁴. We used logistic regression to estimate odds ratios and betas, 95% confidence intervals and P values for trend, using additive coding for genotypes (0, 1 or 2 minor alleles). For autosomal regions, we used a score test, whereas for regions on ChrX we used the ChrX-specific SNPTEST method Newml. QC was performed directly after association testing, excluding any SNPs with an INFO score of <0.80, HWE P<1×10⁻⁶, and MAF<0.01 (overall). In all analyses, we adjusted for both gender and ancestry by conditioning on gender and the first ten principal components derived from EIGENSTRAT PCA⁷⁹. The λ_(GC) values for all cohorts were within acceptable limits; the highest was observed for the cohort with the largest case sample size, namely, CD (λ_(GC)<1.07), consistent with what was previously reported for this data set. In fact, we have previously reported on all the non-CHOP cases included in the present analysis in individual studies using CHOP controls and shown that these individual case-control analyses were well controlled for genomic^(61,62,63,64,65,66,67,68,69,70). A QQ plot is provided for each independent cohort in FIG. 2C-1. Meta-Analysis to Identify Shared pAID Association Loci. To identify association loci shared across pAIDs, we meta-analyzed the summary-level test statistics from each of the study cohorts after extracting those markers that passed post-association testing QC for all ten individual disease-specific analyses. To adjust for confounding due to the use of a shared or pooled control population, we applied a previously published method to perform an inverse weighted χ² meta-analysis⁸⁰. We LD-clumped the results of the meta-analysis (PLINK) and identified 27 LD-independent associations (r²<0.05 within 500 kB up- or downstream of the lead or most strongly associated SNP) reaching a conventional genome-wide significance threshold of P_(META)<5×10⁻⁸. We observed that the calculated meta-analysis λ_(GC) was less than 1.09. As recently discussed by de Bakker and colleagues and shown in a number of large-scale GWAS publications, λ_(GC) is related to sample size. As discussed by Yang et al., λ_(GC) depends on the relative contribution of variance due to population structure and true associations versus sampling variance: with no population structure or systematic error, inflation would still depend on heritability, genetic architecture and study sample size⁸². On the basis of de Bakker et al.'s recommendations, we also calculated a sample-size-adjusted λ₁₀₀₀ by interpolating the λ_(GC) that would have been expected if this study had included only 1,000 cases and 1,000 controls. We performed this only for the meta-analysis results, as the case and control counts for the meta-analysis were both significantly greater than 1,000 (Supplementary Table 1a). Model Search to Identify pAIDs Associated with the Lead Signals. The meta-analysis identified SNPs significantly associated with at least one pAID. To determine which pAIDs each SNP was most strongly associated with, we performed a model or ‘disease-combination’ search. For the lead SNP in each pAID-association locus, we searched for the pAID disease combination that, when the corresponding cases were merged in a mega-analysis, yielded the largest association test statistic. To identify the disease phenotypes most likely contributing to each identified association signal, we applied the “h.types” method as implemented in the R statistical software package ASSET⁸³ to perform an exhaustive disease-subtype model search. Note that ASSET provides both a method for genotype-level association testing (h.types used in this study) and a summary-level modified fixed-effect meta-analysis approach (“h.traits”) that allows for heterogeneity of SNP effects across different phenotypes. Both methods exhaustively enumerate each combination of phenotypes that are jointly considered, and therefore test a total of where r is the total number of disease subtypes assigned to cases (for example, ranging from one to ten pAIDs) and n is the total number of disease subtypes (i.e., ten pAIDs). Note that this reduces to 2^(n)−1 (or 1,023 unique combinations here), as in this case we considered all possibilities of r across n of ten diseases. The ASSET algorithm iteratively tests each pAID case combination using logistic regression to determine whether there is an association between genotype counts and case status. For each SNP tested, the ‘optimal’ subtype model is the combination of pAIDs that, when tested against the shared controls in the logistic regression analysis produced the best test statistic after the DLM method had been used to correct for multiple testing across all subtype combinations. Identification of Lead Associated Variants Showing Opposite Direction of Effect. For each of the top 46 associating loci (P_(META)<1×10⁻⁶), we identified those loci for which the lead SNP had an effect direction (on the basis of logistic regression betas) opposite that reported for the disease combination identified by the subtype model search and whose corresponding association P value reached at least nominal significance (P<0.05). We identified nine instances. Candidate Gene Prioritization. To annotate the lead SNPs to candidate genes, we prioritized the mapping to candidate genes systematically in the following manner:

-   -   1. If the SNP or locus was previously reported in autoimmune         diseases at genome-wide significance, we provided the candidate         gene symbol, where available, as identified in the GWAS Catalog         or ImmunoBase.     -   2. If an SNP was annotated as coding or fell within the coding         DNA sequence (i.e., intronic or in the UTRs), we reported that         gene as identified by the variant effect predictor (VEP).     -   3. If the SNP was upstream, downstream, or intergenic, we         prioritized the gene by using the best candidate gene identified         with the network tool DAPPLE⁸⁶.     -   4. If none of the above was feasible, we manually curated the         most ‘likely’ gene on the basis of the observed LD block and         evidence of prior association signals with autoimmune diseases         or other immune-related phenotypes as presented in the dbSNP or         GWAS catalog.         Functional or Biological Annotations and Enrichment Analysis         Using Publicly Accessible Resources.         We annotated the lead pAID-associated SNPs using publicly         available functional and biological databases and resources. We         considered the top imputed lead SNP for each locus and, in         addition, any of its near-perfect proxies (defined as r²>0.8         within 500 kB up- or downstream) on the basis of the 1KGP-RP.         We included annotation, expression, interaction and network data         from the following resources:     -   1. Genomic mapping and annotation: SNAP⁸⁷, SNP-Nexus⁸⁸,         Ensemble⁸⁹ and UCS⁹⁰.     -   2. Regulatory annotations: EnCODE (TF-binding sites and         DNase-hypersensitivity sites)⁹¹, GTex⁹² (eQTLs), and a published         lymphoblastoid cell line eQTL data set⁹³.     -   3. Functional annotations: SIFT, Polyphen⁹⁵, miRNA target site         polymorphisms^(96,97).     -   4. Conservational or evolutionary predictions: GERP⁹⁸,         PHAST++⁹⁹, CpG islands¹⁰⁰.     -   5. Literature search: GAD¹⁰¹, NHGRI GWAS catalog¹⁰², dbGAP¹⁰³,         or published Immunochip studies¹⁰⁴ (http://www.immunobase.org)         for literature support.     -   6. Gene expression and enrichment analysis: ImmGen¹⁰² (murine)         and whole-transcriptome analysis across 126 tissues¹⁰⁴ (human).     -   7. Protein-protein interaction (PPI) database: DAPPLE⁸⁶,         STRING¹⁰⁵.     -   8. Pathway-based and gene set enrichment analysis: Gene         Ontogeny¹⁰⁶, Webgestalt¹⁰⁷, Wikipathways¹⁰⁸, IPA¹⁰⁹, DAVID¹¹⁰,         GSEA¹¹¹ and Pathways Commons¹¹².     -   9. Gene network analysis and visualization: DAPPLE⁸⁶ and VEP⁸⁵         to prioritize candidate causal genes and Grail¹¹³ for         text-mining of PubMed database for coassociations.         Functional and biological annotations (categories 1-5) for the         27 lead SNPs are illustrated in FIG. 3a ; annotations are also         provided for the 46 GWM loci in FIG. 4D. The following         annotation types were used:     -   1. Regulatory: EnCODE consensus TF-binding sites (T), DNase I         hypersensitivity sites (S), or published eQTL signals (E)     -   2. Functional: known mutations in PolyPhen or SIFT (A),         experimentally validated (miRBASE 18.0) and predicted (mirSNP)         miRNA target sites (R), or SNPs that tag regions containing         common copy-number variation regions reported by the database of         genomic variants (DGV) (V)     -   3. Conserved: conserved nucleotide sequences based on         GERP++/phastCon (C) or known CpG islands that correlate with         epigenetic methylation patterns (M)     -   4. Literature-supported: published association with immune or         inflammatory diseases or immune-related endophenotypes from         candidate studies or GWASs catalogued in the Genetic Association         Database, NHGRI GWAS catalog, dbGAP, or Immunochip studies (L)         In addition to determining whether the 27 GWS pAID-associated         SNPs were enriched for a given annotation type, we performed         Monte Carlo simulations to resample 10,000 times the SNPs         (MAF>0.01 in Europeans) from all SNPs in 1KGP-RP. As for the 27         lead SNPs, for each set of 100 randomly sampled SNPs, we         expanded the list by first identifying all nearby SNPs in strong         LD (i.e., LD proxies with r²>0.8 within 500 kB up- or         downstream) within the 1KGP-RP data set filtered for only SNPs         with MAF>0.01 in the European population. We then annotated each         original and any proxy SNPs as above for each major annotation         category. We collapsed the information for all proxies         identified for a given lead such that for any given category, if         the lead SNP or any of its proxies were annotated, the lead SNP         was marked as annotated. We then calculated the frequency of         annotation for the 100 SNPs in each set. After sampling and         annotating 100-SNP sets 10,000 times, we use the         permutation-derived distribution of annotation percentages for         each annotation type to calculate an enrichment P value such         that where N is the number of permutations, f is the percentage         of SNPs in the pAID set that are annotated and F is the         distribution of the percentage of SNPs annotated across 10,000         sets of 100 SNPs resampled from the 1KGP-RP using only markers         with MAF>0.01 in Europeans.         Hierarchical Clustering Based on Effect Size and Direction of         Association.         We performed agglomerative hierarchical clustering across the         top 27 independent loci using the directional Z-score obtained         from logistic regression analysis in each of the ten         disease-specific GWASs, defined as where beta is the effect         size. The standardized and normalized Z-scores were used as         inputs to the agglomerative hierarchical clustering. We used         Ward's minimal-variance method to identify relatively consistent         gene and locus cluster sizes.         Gene-Based Association Testing.         Given our interest in genetic overlap across pAIDs, we sought to         identify genes associated with pAIDs in a disease-agnostic         manner that was insensitive to locus and phenotypic         heterogeneity. We used VEGAS¹¹⁴, a set-based method, to perform         GBAT. As input, we used the nominal P_(META) values from the         pooled, inverse χ² meta-analysis for the ten pAIDs across the         genome as the input summary statistics for VEGAS, without         considering which specific diseases were identified in the model         search analysis. We assigned SNPs to gene regions and performed         10⁷ simulations to estimate the gene-based P value as described         in VEGAS's documentation. We used two thresholds:         P_(sim)<2.8×10⁻⁶ to identify significant candidate genes, on the         basis of a Bonferroni adjustment for approximately 17,500 genes         tested, and a false discovery rate (FDR) of <2%, which         corresponds to a q value of <0.0205, which was used only for         pathway and gene set enrichment analysis.         Tissue-Specific Gene Set Enrichment Analysis.         With few exceptions, most genes that are known to have a         causative role in autoimmune disease have been shown to regulate         molecular or subcellular processes in immune or immune-related         tissues. If candidate pAID-associated genes are relevant to         autoimmune-disease biology, then expression of these genes would         be expected to be, on average, higher across immune or         immune-related tissues (as compared with expression in         non-immune-related tissues). Thus, we compared the expression of         candidate pAID-associated genes identified by GBAT with that of         non-candidate genes in a variety of tissues.         We curated the expression of the transcriptome in a broad         spectrum of human tissues using a publicly available data set         consisting of summary-level, normalized gene expression levels         for more than 12,000 unique genes across 126 tissues and/or cell         types, including a large number of immune tissues and cells¹⁰⁴.         We downloaded the processed data set “mean expression data         matrix.”         Across the 126 unique tissues, we tested whether the median or         cumulative distribution of expression of pAID-associated gene         transcripts as identified by GBAT was higher than that of the         remaining transcripts in the data set using a one-sided Wilcoxon         rank test or a one-sided Kolmogorov-Smirnov (KS) test,         respectively. We calculated a tissue-specific gene expression ES         value, which is the −log₁₀ (P value) obtained from comparing the         relative enrichment in transcript expression of pAID-associated         genes versus the transcripts of the remaining genes in the data         set. The tests were done on a per-tissue basis to derive a set         of KS and a set of Wilcoxon ES values. We performed this per         tissue analysis (1) for the total set of pAID-associated genes         from GBAT and (2) when genes across the extended MHC (chr6:         25-34 Mb) were excluded.         We performed the secondary immune-versus-non-immune comparative         analysis by plotting the ES values obtained from either Wilcoxon         or KS tests in descending rank order of the respective test         statistics, as shown in FIG. 4a and FIGS. 5D and 5E for all 126         tissue types. In those figures each point represents a single         tissue and is colored according to its classification as either         immune (red) or non-immune (blue), as described previously⁸⁶.         To formally test whether the overall ES values were higher among         immune tissues than among non-immune tissues, we performed both         the Wilcoxon rank sum test and the KS test on the vector of         per-tissue ES values, comparing those derived from immune and         non-immune tissues. We found that the enrichment observed across         immune tissues was specific and not general to any         GWAS-identified signals. We repeated this analysis in two sets         of candidate genes, one for CD and another for schizophrenia, by         identifying all associated genes for the two phenotypes from the         NHGRI GWAS Catalog.         Immune Cell Gene Set Enrichment Analysis.         Cells of the immune system are extremely diverse in function and         gene expression. To more precisely assess the expression of         pAID-associated genes, we examined the mRNA expression of pAID         candidate genes across specific immune cell subtypes, as well as         during different developmental time points.         ImmGen provides a publicly available, high-quality murine gene         expression data set. The ImmGen data set consists of 226 murine         immune cell types across different lineages at multiple         developmental stages, sorted by FACS and assayed at least in         triplicate. Standard QC and quantile-normalization methods were         applied to the data set as described by ImmGen¹⁰². The total set         of transcripts mapped to 14,624 homologs in the human         transcriptome on the basis of genes annotated in the         hg18/build36 of the human reference genome, which were used to         query the gene expression data.         Some of the cell types were derived from genetically altered         animals, and the results from analysis of those cell types would         have been difficult to interpret, so we removed those cell lines         from the analysis. The complete list of cell types used in the         analysis and the category to which we assigned each cell type         for the categorical analysis are presented in Table 3c. A total         of 176 unique cell lines remained for subsequent analyses using         this data set.         As with the human data set, we calculated the ES values by         comparing the expression of the pAID-associated candidate gene         transcripts to that of the remaining transcripts assayed in the         data set for each immune cell type examined. We plotted the         distribution of relative gene expression ES values as a density         plot across the range of ES values from all of the examined cell         types available. We compared the results obtained using the full         set of candidate pAID genes identified by GBAT or obtained when         we excluded the genes within the extended MHC. To ensure that         this was not simply a result of selection bias (as GWASs may be         biased toward regions or genes across the genome that are better         sampled or more densely genotyped), we compared the results to         those obtained with the curated gene lists from the GWAS catalog         (as above) for CD, schizophrenia, body mass index and LDL         cholesterol.         To determine whether pAID-associated candidate genes are         expressed at higher levels (relative to the rest of the genes in         the transcriptome) in some immune cell types than in others, we         defined immune cell types according to surface marker expression         and tissue isolation details provided by ImmGen. Some categories         were further divided into subcategories (for example, B and T         cells) on the basis of developmental stage or lineage into a         total of 16 non-overlapping cell-type categories. To compare the         results across the cell-type categories, we plotted the         distribution of ES value ranks for each cell type, binning the         results according to the category each cell type belonged to         (again, we performed the analysis either with or without the         extended MHC region).         Expression Profiling of Pleiotropic Autoimmune         Disease-Associated Genes Across Specific Immune Cell Types.         We profiled the expression of genes that had been identified in         at least three autoimmune diseases in our subtype model search,         previously published Immunochip fine-mapping studies, or a         combination thereof (for example, identified as associated with         JIA and UC in our analysis but previously identified as a         candidate gene from an Immunochip analysis of alopecia areata).         We identified 217 candidate pleiotropic genes, of which 191         could be mapped to unique gene transcripts within the ImmGen         data sets.         We performed agglomerative hierarchical clustering with the         matrix of gene expression levels from the 191 candidate gene         transcripts using Ward's minimal-variance method across all 176         immune cell types. The genes and cell types shown in dendrograms         are based on the results of unsupervised hierarchical clustering         analysis and represent four major groups of cells and six major         groups of genes.         We examined whether genes that were clustered on the basis of         similar immune cell-expression profiles were likely to be         associated with the same disease(s). Specifically, given a set         of genes associated with one or more autoimmune diseases grouped         in cluster i (C_(i)), we asked whether there is an increased         likelihood (i.e., more so than expected by chance as compared         with genes not found within this cluster) that these genes are         also associated with disease j (D_(j)), such that where the         expected probability of the values observed under the null is         given by the hypergeometric distribution. As some of the cell         counts were small and we were interested only in identifying         instances where a>>b, c or d, we used a one-sided Fisher's exact         test. We first tested each of the 18 autoimmune diseases across         all identified clusters, declaring nominal and         Bonferonni-adjusted significance at P<0.05 and P<5.6×10⁻⁴,         respectively. For any clusters where at least two diseases         reached nominal or marginal significance, we also tested whether         there was an overrepresentation of genes associated with both         diseases at P<0.05.         PPI and Network Analysis.         DAPPLE⁸⁶: PPIs among the set of either 27 GWS or 46 GWM         candidate regions were identified; the input seeds were defined         as the 100-kB sequences up- and downstream of the most         significantly associated SNP (based on hg19) in each candidate         region. Other input parameters included 50-kB regulatory region         length, a common interactor binding degree cutoff of 2, and the         following specified known genes: IL23R, PTPN22, INS, NOD2, DAG1,         SMAD3, ATG16L1, ZNF365, PTGER4, NKX2-3, ANKRD55 and IL12B. We         performed 10,000 permutations to accurately calculate enrichment         network statistics. Seed scores P_(dapple) were used to color         the protein nodes in the network plot.         STRING¹⁰⁵: We used the Homo sapiens PPI database to query one of         three lists: (1) the GWS loci, (2) GWS and GWM loci or (3) the         list of genes identified by GBAT shown to be enriched for key         proteins in the JAK-STAT pathway. We assessed and reported the         evidence of PPI enrichment on the basis of these queries as         compared to the results expected for the rest of the genes in         the human genome. We generated network plots for the directly         connected protein candidates (FIGS. 6A-6C represents the         “evidence” plot option).         Pathway and Gene Set Enrichment Analysis.         Webgestalt¹⁰⁷: For pathway and gene set analysis, we used the         web-based tool Webgestalt to examine evidence of shared TF         binding, miRNA target-binding sites, and enrichment in specific         Gene Ontology and Pathway Commons categories. The inputs for         this analysis included all lead genes (FDR<2%) from the GBAT         (similar to that for the other pathway annotation databases         below for consistency).         DAVID¹¹⁰: We used the bioinformatics web tool DAVID (v6.7,         available at http://david.abcc.nciferf.gov) for         functional-annotation analysis of the significant genes.         Significant genes with FDR<2% in VEGAS, the gene-based         association analysis, were used as input for DAVID. DAVID         performed overrepresentation analysis of functional-annotation         terms on the basis of hypergeometric testing and adjusted for         multiple testing. To compare the results of this analysis with         results obtained via other methods, we used BioCarta, KEGG         pathways and GO BP FAT as gene set definition files.         IPA¹⁰⁹: We used IPA software (http://www.ingenuity.com/) for         canonical pathway and network analysis. We inputted all the         significant genes in the VEGAS output (FDR<2%) for IPA analysis.         In the IPA core analysis, we selected the Ingenuity Knowledge         Base (Genes Only) as the reference set, including both direct         and indirect relationships. We used the filter setting of         relationships in human and experimentally observed only.         Information regarding canonical pathways was obtained from IPA         output.         GSEA^(115,116): We conducted gene set enrichment analysis with         the software GSEA (http://www.broadinstitute.org/gsea) using as         input the pre-ranked gene list generated on the basis of the         −log(P value) from VEGAS using all genes. We selected the         following settings for our analysis: number of permutations,         5,000; enrichment statistic, weighted; maximum size of gene set,         500; minimum size of gene set, 15; and with normalization.         Interdisease Genetic Sharing Analysis.         To examine the degree of overlap in genetic risk susceptibility         between any two autoimmune diseases, we developed and/or         implemented the following statistical measures to quantify         interdisease genetic sharing:     -   1. LPS test, optimized to evaluate whether two pAIDs share more         loci in common than would be expected to occur by chance; the         score ‘penalizes’ disease pairs if many of the loci are disease         specific. The test is helpful if only data on whether diseases         share specific candidate genes or association loci in common are         known.     -   2. GPS test, optimized to assess the correlation between the set         of association test statistics observed genome-wide across any         two pAIDs. This test is valuable because it is independent of         the gene sets chosen and thus does not require the use of any         arbitrary method to define a significance ‘threshold’ of input         data.         LPS Analysis.         To quantify the similarity between any two diseases D₁ and D₂ on         the basis of the degree to which D₁ and D₂ share independent         genetic risk associations (i.e., loci, SNPs or candidate genes),         we considered the following model.         We began with a list of candidate genes, association loci or         LD-independent SNPs n_(r) identified as having reached a         predefined GWAS significance threshold (e.g., GWS or GWM) across         one or more SNPs from n_(r) for a set of diseases with expected         or hypothesized sharing (i.e., all autoimmune diseases in this         study and those reported on by the Immunochip studies catalogued         by ImmunoBase⁸³).         For any two diseases D₁ and D₂, a given candidate gene or SNP         x_(i) could be uniquely classified in one of four ways:         associated with D₁ and D₂ (n₁₁), associated only with D₁ (n₁₂)         or D₂ (n₂₁), or associated with neither D₁ nor D₂ (n₂₂). For any         given list of TOP associations (i.e., n_(r)), the distribution         across the four possible categories can be tabulated as follows:

Locus x_(i) D₂ (yes) D₂ (no) D₁ (yes) n₁₁ n₁₂ D₁ (no) n₂₁ n₂₂ where n₁₁+n₁₂+n₂₁+n₂₂=n_(r) and D₁ (yes) or (no) means the SNP x_(i) is or is not associated with that marker, respectively. The probability P_(x) that an SNP x_(i) from the list n_(r) is associated with either D₁ or D₂ can be expressed as:

$P_{1} = {\frac{n_{11} + n_{12}}{n_{r}}\mspace{14mu}\left( {{for}\mspace{14mu} D_{1}} \right)}$ $P_{2} = {\frac{n_{12} + n_{21}}{n_{r}}\mspace{14mu}\left( {{for}\mspace{14mu} D_{2}} \right)}$ for any two pAIDs D₁ and D₂. Thus, the frequency at which x_(i) should truly be associated with two distinct disease subtypes is given by n_(r)(P₁P₂), and the observed number of overlapping associations is represented by n₁₁. Therefore, under the null hypothesis H₀, for a given pair of diseases D₁ and D₂, the variance of the difference between the numbers of expected and observed associations of all those tested (n_(T)) shared by both D₁ and D₂ should follow a normal distribution.

$z = {\left. \frac{n_{11} - {n_{r}\left( {P_{1}P_{2}} \right)}}{\sqrt{{n_{r}\left( {P_{1}P_{2}} \right)}\left( {1 - {P_{1}P_{2}}} \right)}} \right.\sim{N\left( {0,1} \right)}}$ We used the one-sided Z-test to examine whether the degree of overlap was significantly greater than expected, assuming a normal distribution under the null hypothesis that D₁ and D₂ do not share more associations than they would by chance. We used a Bonferroni adjustment to correct for 45 pairwise disease-combination tests. GPS Analysis. The GPS test determines whether two pAIDs are genetically related. For the ith SNP, let X_(i)=1 if the SNP is truly associated with one disease, and let X_(i)=0 otherwise. Similarly, define Y_(i) as the indicator of whether the SNP is associated with the other disease in the pair. We can therefore consider the diseases to be genetically related if there are more SNPs with (X_(i),Y_(i))=(1,1) than would be expected to occur by chance. This amounts to testing the independence of X_(i) and Y_(i). However, we do not directly observe X_(i) and Y_(i) and instead observe P values U_(i) and V_(i), which come from the two GWAS studies for the two diseases. When X_(i)=1, the P value U_(i) will tend to be small, and otherwise U_(i) will be uniformly distributed; the same is true of Y_(i) and V_(i). If U_(i) and V_(i) are independent, then X_(i) and Y_(i) must be as well. We can therefore test for genetic relatedness by testing whether the P values are dependent. Most existing methods may not take advantage of the availability of the full genome data set for testing genetic sharing using U_(i) and V_(i). To address this limitation, we developed a novel, threshold-free method to detect genetic relatedness. Our test statistic is defined by

$D = {\sup\limits_{u_{x}v}\sqrt{\frac{n}{\ln\; n}}\frac{{{F_{uv}\left( {u,v} \right)} - {{F_{u}(u)}{F_{v}(v)}}}}{\sqrt{{{F_{u}(u)}{F_{v}(v)}} - {{F_{u}(u)}^{2}{F_{v}(v)}^{2}}}}}$ where n is the total number of SNPs, F_(uv)(u,v) is the empirical bivariate distribution function of (U_(i),V_(i)), and F_(u)(u) and F_(v)(v) are the empirical univariate distribution functions of U_(i) and V_(i), respectively. Intuitively, the numerator of D is motivated by the fact that if U_(i) and V_(i) are truly independent, their bivariate distribution is equal to the product of their univariate distributions. The denominator of D makes the test capable of detecting even very weak correlations. Under the null hypothesis of no genetic sharing, it can be shown that D is approximately distributed like the inverse square root of a standard exponential random variable. This gives us an analytic expression for calculating P values. Note that no significance threshold is required. The asymptotic null distribution of D is derived under the assumption that the genetic markers examined across the genome are statistically independent. We therefore pruned the SNPs for each pair of diseases before applying our test. We conducted inverse χ² meta-analyses separately for each pair of diseases and pruned the resulting P values using a threshold of r²<0.5 within a 500-kB up- and downstream region. This left about 800,000 SNPs for each disease pair analyzed. The use of more stringent r² thresholds (for example, r²<0.3 or 0.2) gave comparable results. Undirected Weighted Cyclic Network Visualization of Results from the Locus-Specific Sharing Test. In graphic representations, pairwise relationships between autoimmune diseases (nodes) are represented by edges, whose weights are determined by the magnitude of the LPS test statistic (R statistical software package q-graph). Specifically, the width and density of the edges are the standardized transformations of the test statistic, and the colors denote whether the direction of the test statistic is positive (blue, meaning more sharing than expected) or negative (red, meaning less sharing than expected). Although graphs are constructed from all 45 pairwise interactions, for simplicity and improved visualization, we showed only those edges that represented a pairwise interaction that reached a Bonferroni-adjusted or nominal (FIG. 7) significance threshold (P<0.05). The nodes are positioned on the basis of a force-directed layout based on the Fruchterman-Reingold algorithm. In Silico Replication of Novel pAID-Association Loci Using Previously Published Autoimmune Disease Cohort Data Sets. Replication set I: The following data sets were used in the first replication set: CASP¹¹⁷, CIDR Celiac Disease¹¹⁸, NIDDK Crohn's Disease¹¹⁹, Wellcome Trust Case Control Consortium (WT) Crohn's Disease and Type 1 Diabetes¹²⁰, WT Ulcerative Colitis¹²¹ and WT Ankylosing Spondylitis¹²². These data sets were obtained via dbGaP or the Wellcome Trust Case Control Consortium. In order to maximize the power, we sought replication for each of the 12 significant SNPs in all of the seven available data sets. Full results are summarized in Table 2e. Each data set was subjected to strict QC filtering as follows: we removed individuals that were inferred to be related on the basis of genetic data, individuals with >10% missing data, individuals with a reported sex that did not match the observed heterozygosity rates on chromosome X, and individuals not of European ancestry. We further removed variants with >10% missingness, variants not in HWE, variants with missingness significantly correlated to phenotype, and variants with MAF<0.005. Variants to be replicated that were not observed in the original data set were imputed using IMPUTE2 (ref. 123) and the 1KGP-RP haplotype data¹²⁴. Markers across the X chromosome, which were previously considered by most of these studies, were reanalyzed using the WAS toolset^(125,126). Replication-association analysis was carried out by logistic regression implemented in PLINK¹²⁷. The first ten principal components calculated using EIGENSOFT¹²⁸ were added as covariates for all data sets except CASP, where no population stratification was observed. Replication set II: The second replication set consisted of the following data sets: Rheumatoid Arthritis meta-analysis¹²⁹, IBDG Ulcerative Colitis meta-analysis¹³⁰, IBDG Crohn's Disease meta-analysis¹³¹, Systemic Lupus Erythematosus GWAS, and SLEGEN¹³³. Individuals from these data sets were of European ancestry. Summary statistics from the original studies were publicly available and were used for the replication analysis. Details regarding QC procedures and association analysis can be obtained from the original studies^(129,130,131,132,133). LD-based replication for replication sets I and II: We further assessed replication in SNPs that were in LD with the significant SNPs in the discovery set. For each associated SNP, a list of SNPs in LD (r²>0.5) within 500 kb of the original SNP was obtained from SNAP⁸⁷ using the 1KGP-RP. List of Tables as Described and Referred to within the Main Text or Methods Supplementary Table 1: The 10 study cohorts and leading 27 GWS loci associated with pediatric autoimmune diseases.

-   (a) The 10 pAID cohorts and common controls. The ratio of female to     male subjects (F:M), and the genomic inflation factor (.lamda.GC)     for each cohort and from the inverse chi-square meta-analysis     calculated either with and without (exMHC) markers in the Major     Histocompatibility Region (MHC) region. .lamda.GC adjusted for an     expected study cohort of 1000 cases and 1000 controls (.lamda.1000). -   (b) Autoimmune diseases associated with the 27 GWS candidate genes.     Novel loci are denoted with an asterisk; underlined circles or Xs     denotes instances of in silico replication in an independent     dataset. -   (c) In silico replication for the five putatively novel GWS loci.     Abbreviations: CHR: chromosome; SNP: rsID dbSNP 138; POS: position     in hg19; GENE: Candidate Gene Name (HGNC); REGION: Cytogenetic band;     P META: disease-specific GWAS logistic regression P-value; P_REP:     Disease-specific replication P-value in the specified dataset; AI-D:     replication cohort autoimmune disease -   (d) Summary statistics tabulating key attributes across respective     categories for the set of 27 GWS loci (See text for details).     Abbreviations: Num: Number; prey: previously -   (e) Sanger validation results for five randomly-selected imputed     SNPs (f) Imputation concordance for select samples genotyped on the     Immunochip.

SUPPLEMENTAL TABLE 1a The 10 pAID cohorts and 27 genome-wide significant loci identified in this study Ab pAID Count F:M GIF GIF THY Thyroiditis 97 0.76 1.016 1.018 AS Ankylosing Spondylitis 107 0.55 1.014 1.013 PS Psoriasis 100 0.58 1.012 1.010 CEL Celiac Disease 173 0.63 1.018 1.016 SLE Systemic Lupus Erythematosus 254 0.88 1.017 1.018 CVID Common Variable 308 0.54 1.010 1.010 UC Ulcerative Colitis 865 0.54 1.023 1.019 T1D Type 1 Diabetes 1086 0.49 1.047 1.044 JIA Juvenile Idiopathic Arthritis 1123 0.69 0.988 0.982 CD Crohn's Disease 1922 0.42 1.069 1.069 CTRL Non-AID Ascertained Controls 10718 0.48 — — average Across 10 case-control 6035 0.46 1.021 1.020 merge studies 1.096^(e) 1.012^(f) 1.089^(e) 1.011^(f) Meta Inverse chi-sq meta-analysis 1.085^(e) 1.011^(f) 1.078^(e) 1.010^(f)

SUPPLEMENTAL TABLE 1b The 10 pAID cohorts and 27 genome-wide significant loci identified in this study AS PS CEL SLE CVID US T1D JIA CD AA MS PBC PSC RA SJO SSC VIT THY IL23R X X O O O X O O X O O O O O O O O O LPHN2* O O O O X O O X O O O O O O O O O O PTPN22 O X O X O O X X X O O O O X O O X X TNM3* X O X X X O O X O O O O O O O O O X ANKRD30A* O O O O O O O X O O O O O O O O O O INS O O O O O O X O O O O O O O O O O O NOD2 DAG1 O X X O O X O O X O O O O O O O O O SMAD3 ATG16L1 O X O O O O O O X O O O O O O O O O ZNF365 PTGER4 O O O O O X O O X O X O O O O O O O NKX2-3 ANKRD55 O O O O O O O X X O X O O X O O O O IL128 LRRK2 X O O O O O O O X O O O O O O O O O IL5 SUOX O X O O O O X O O O O O O O O O O O SBK1 X X X O O X O O X O O O O O O O O X ADCY7* O X O O O O O O X O O O O O O O O O IL2RA X X X O O O X X X X X O X X O O X X TNFSF15 O O O O O X O O X O O O O O O O O O CD40LG* O O X O O X O O X O O O O O O O O O ZMIZ1 X X X O O O O O X O X O O O O O O O IL21 X O X O X X X X X X O O X X O O O X CARD9 X O O O O X O O X O O O O O O O O O PSMG1 O O O O O X O O X O O O O O O O O O

SUPPLEMENTAL TABLE 1c The 10 pAID cohorts and 27 genome-wide significant loci identified in this study REGION SNP GENE P_META P_REP AI-D 1p31.1 rs2066363 LPHN2 8.38E−11 1.69E−02 UC 4q35.1 rs7660520 TNM3 8.38E−11 3.65E−03 PS 16q12.1 rs77150043 ADCY7 5.99E−09 4.98E−04 CD Xq26.3 rs2807264 CD40LG 1.25E−08 4.66E−05 UC Xq26.3 rs2807264 CD40LG 1.25E−08 9.54E−03 AS Xq26.3 rs2807264 CD40LG 1.25E−08 5.81E−04 CD

SUPPLEMENTAL TABLE 1d The 10 pAID cohorts and 27 genome-wide significant loci identified in this study Category Description Count Total SNP-pAID pairs identified 77 Num of Pairs prev known 44 Num of Pairs novelly reported 33 Novel loci (no prev reported Al disease) 5 Loci assoc with 2 or more pAIDs 22 Loci assoc with at least one novel pAID 16 Pleiotropic Loci (>3 diseases) 11

SUPPLEMENTARY TABLE 1e Imputation concordance for imputed SNPs assessed by Sanger Sequencing across random samples Alleles correct (per sample) rs13089824 rs11691517 rs9833463 rs13288173 rs1932990 Not assessed* 2 3 3 0 0 0 0 2 0 1 0 1 1 5 2 1 0 2 189 180 187 190 192 Total alleles correct 379 365 376 381 384 Percent correct 99.74% 97.59% 99.47% 99.22% 100.00% Mean Accuracy Min Accuracy Max Accuracy Stdev Accuracy 99.20% 97.59% 100.00% 0.95%

SUPPLEMENTARY TABLE 1f Imputation concordance for samples that were also directly genotyped on the immunochip platform; CVID (269 subjects) All % min max Overlapping Concordance Imputed % Imputation maf maf SNPs all Overlapping Concordance 0.01 0.05 520 99.77% 482 99.76% 0.05 0.10 800 99.76% 688 99.73% 0.10 0.20 1127 99.72% 917 99.67% 0.20 0.30 1005 99.74% 818 99.68% 0.30 0.40 849 99.67% 686 99.60% 0.40 0.50 855 99.71% 690 99.66% 0.01 0.50 5225 99.73% 4340 99.68% IBD (281 subjects) 0.01 0.05 560 99.77% 518 99.76% 0.05 0.10 873 99.77% 752 99.74% 0.10 0.20 1254 99.71% 1023 99.66% 0.20 0.30 1106 99.68% 904 99.63% 0.30 0.40 920 99.62% 744 99.56% 0.40 0.50 942 99.57% 762 99.50% 0.01 0.50 5730 99.68% 4765 99.64% **Note that the total overlapping SNPs are those after QC filtering for both platforms and samples to keep SNPs with minor allele freq >0.01, individual missingness <0.05, genotyping rate >0.95 and hardy-weinberg >1e−06 ***The imputed columns excluded snps that were directly genotyped on both platforms from the analysis; to strictly assess imputation concordane with ichip genotypes

TABLE 2a The 46 pAID association loci reaching GWM significance (P_META < 1 × 10⁻⁶). CHR POS(Mb) SNP REGION GENE Al MAFCASE MAFCTRL P_(META) Known_P* pAIDs 1 67.7 rs11580078 1p31.3 1L23R G 0.35 0.43 8.4E−11 1.0E−146 CD# 1 82.2 rs2066363 1p31.1 LPHN2 C 0.16 0.34 8.4E−11 novel CVID|JIA 1 114.3 rs6679677 1p13.2 PTPN22 A 0.15 0.09 8.4E−11 1.1E−88 THY#|PS|T1D#|JIA# 1 172.8 rs34884278 1q24.3 TNFSF18 C 0.35 0.30 4.3E−07 1.4E−10 CD# 1 197.4 rs6689858 1q31.3 CR61 C 0.33 0.29 1.7E−07 4.3E−12 AS|CD# 1 206.9 rs55705316 1q32.1 1L10 G 0.16 0.14 9.5E−07 1.9E−09 PS|SLE#|UC#|CD# 2 2.9 rs114846446 2p25.3 TSSC1 A 0.02 0.01 2.4E−07 novel PS|SLE|UC|CD# 2 103.1 rs2075184 2q12.1 1L18R1 T 0.26 0.23 9.4E−08 1.2E−16 THY|CEL#|UC|CD# 2 234.2 rs36001488 2q37.1 ATG16L1 C 0.40 0.48 8.4E−11 1.0E−12 PS|CD# 2 241.6 rs4676410 2q37.3 GPR35 A 0.24 0.19 1.5E−07 2.2E−20 AS#|SLE|UC# 3 49.6 rs4625 3p21.31 DAG1 G 0.37 0.31 8.4E−11 1.0E−47 PS#|CEL|UC#|CD# 4 5.0 rs7672495 4p16.2 CYTL1 C 0.21 0.18 1.0E−07 novel THY|AS|CEL|UC|T1D|JIA|CD 4 123.6 rs62324212 4q27 1L21 A 0.46 0.42 2.6E−08 1.0E−09 THY|AS|CEL#|CVID| UC#|T1D#|JIA#|CD# 4 183.7 rs7660520 4q35.1 TNM3 A 0.35 0.26 8.4E−11 novel THY|AS|CEL|SLE|CVID|JIA 5 40.5 rs7725052 5p13.1 PTGER4 C 0.37 0.43 8.4E−11 1.4E−10 CD# 5 55.4 rs7731626 5q11.2 ANKRD55 A 0.34 0.39 1.4E−10 2.7E−11 JIA#|CD# 5 96.2 rs4869313 5q15 ERAP2 T 0.46 0.42 9.1E−08 1.9E−20 CEL|JIA#|CD# 5 131.8 rs11741255 5q31.1 IL5 A 0.47 0.42 1.6E−09 1.4E−52 PS#|CEL|CD# 5 158.8 rs755374 5q33.3 1L12B T 0.37 0.32 2.3E−10 1.4E−42 AS|CEL|UC#|CD# 8 138.1 rs7831697 8q24.23 8q24.23 G 0.28 0.25 4.7E−07 novel AS|CEL|T1D|JIA|CD 9 5.0 rs36051895 9p24.1 JAK2 T 0.33 0.29 8.6E−08 1.4E−31 AS|SLE|UC#|CD# 9 12.8 rs7042370 9p23 LURAP1L T 0.52 0.43 1.1E−07 novel JIA 9 117.6 rs4246905 9q32 TNFSF15 T 0.24 0.28 9.5E−49 1.2E−17 UC#|CD# 9 132.7 rs10988542 9q34.11 FNBP1 C 0.11 0.08 6.5E−07 novel THY|AS|JIA|CD 9 139.3 rs11145763 9q34.3 CARD9 C 0.44 0.40 3.3E−08 1.0E−06 AS#|UC#|CD# 10 6.1 rs706778 10p15.1 IL2RA T 0.46 0.41 6.3E−09 1.7E−12 THY|AS|PS#|CEL|T1D#|JIA# 10 37.6 rs7100025 10p11.21 ANKRD30A G 0.59 0.34 8.4E−11 novel JIA 10 64.4 rs10822050 10q21.2 ZNF365 C 0.45 0.39 8.4E−11 5.0E−17 SLE|CD# 10 81.0 rs1250563 10q22.3 ZMIZ1 C 0.24 0.29 1.3E−08 1.1E−30 PS#|CD# 10 101.3 rs1332099 10q24.2 NKX2-3 T 0.52 0.46 9.1E−11 1.0E−54 UC#|CD# 11 2.2 rs17885785 11p15.5 INS T 0.10 0.20 8.4E−11 4.4E−48 T1D# 12 40.8 rs17466626 12q12 LRRK2 G 0.05 0.02 3.2E−10 3.0E−10 AS|CD# 12 56.4 rs1689510 12q13.2 SUOX C 0.39 0.31 4.0E−09 1.1E−10 PS#|T1D# 13 107.1 rs11839053 13q33.3 EFNB2 C 0.04 0.02 9.6E−07 novel CVID|JIA 15 67.5 rs72743477 15q22.33 SMAD3 G 0.26 0.21 8.4E−11 2.7E−19 AS|UC|CD# 16 28.3 rs12598357 16p11.2 SBK1 G 0.42 0.39 4.4E−09 1.0E−08 THY|AS#|PS|CEL|UC|CD# 16 28.8 rs12928404 16p11.2 ATXN2L C 0.41 0.38 5.7E−07 1.0E−08 UC|CD# 16 50.3 rs77150043 16q12.1 ADCY7 T 0.28 0.23 6.0E−09 novel PS|CD 16 50.7 rs117372389 16q12.1 NOD2 T 0.04 0.02 8.4E−11 2.9E−69 CD# 17 38.0 rs12232497 17q12 IKZF3 C 0.49 0.45 2.7E−07 1.0E−07 THY|CEL|CVID|UC#|JIA|CD# 19 10.6 rs62131887 19p13.2 TYK2 T 0.25 0.28 4.3E−07 1.0E−10 THY|SLE|T1D#|JIA#|CD# 19 49.2 rs602662 19q13.33 FUT2 G 0.45 0.49 5.3E−08 1.0E−15 PS|T1D#|CD# 20 62.3 rs2738774 20q13.33 TNFRSF6B A 0.29 0.32 8.5E−07 1.1E−23 THY|PS|SLE|UC#|JIA|CD# 21 40.5 rs2836882 21q22.2 PSMG1 A 0.23 0.27 4.8E−08 2.8E−14 UC#|CD# 23 135.7 rs2807264 Xq26.3 CD40LG C 0.25 0.21 1.3E−08 novel CEL|UC|CD 23 136.0 rs12863738 Xq26.3 RBMX T 0.20 0.17 6.1E−08 novel CEL|JIA|CD Abbreviations in table: CHR: chromosome; SNP: dbSNP rsID; POS (Mb): position in hg19; REGION: Cytogenetic band; Al: alternative allele; MAF: minor allele frequency (all, cases or controls; cases refer to the subjects from diseases indicated in the pAID columns); GENE: candidate gene name (HNGC); PMETA: Meta-analysis P-value of the lead SNP(s); Known-P*: Lowest P-value previously reported by any published autoimmune disease GWAS based on annotations in the GWAS Catalog or published Immunochip studies; “novel” denotes new loci (bolded) reaching GWS for the first time in the present study; pAIDs: combination of pAIDs identified as being associated with the locus based on model search; (#) denotes if the SNP has been previously reported as being associated with a given disease at GWS.

TABLE 2b Previously-reported associations with the top 46 loci in the GWAS Catalog and Immunochip datasets. SNP AA AS CD CeD IBD JIA MS NAR PBC PSC PS RA SJO SLE SSC T1D THY UC VIT GWAS Catalog rs11580078 O O O O CD|2E−7|CD| 1E−8|CD|3E−12| IBD|4E−13 rs2066363 NA rs6679677 O O O X O O X T1D|1E−40| T1D|5E−26| T1D|8E−24| IBD|2E−15|RA| 6E−25|RA|6E−42| CD|2E−15| HTHY|3E−13 rs7660520 NA rs7100025 NA rs17885785 O T1D|5E−196 rs117372389 O O NA rs4625 O O O O O CD|4E−8| CD|5E−8| UC|7E−9|UC| 2E−17|CD| 1E−12| CD|6E−17| IBD|1E−47|PSC| 1E−16|UC|4E−9 rs72743477 O O CD|3E−19|IBD| 6E−16 rs36001488 O O CD|5E−14|IBD| 4E−70|CD| 4E−70|CD| 2E−32|CD| 1E−12|CD| 3E−6|CD|1E−13| CD|5E−9| CD|7E−41 rs10822050 O O O ADER|6E−20| CD|4E−20 rs7725052 O O O X AS|3E−7 rs1332099 X O O O CD|2E−20|IBD| 1E−54|CD|6E−8| CD|4E−10| UC|2E−6| UC|8E−21| UC|2E−7|CD| 3E−16|UC|1E−8 rs7731626 X X X X O NA rs755374 O X O O O UC|1E−21| IBD|1E−42 rs17466626 O O CD|3E−10| CD|6E−21| IBD|6E−29 rs11741255 O O X X X IBD|1E−52| CD|2E−18| CD|1E−7| CD|1E-20 rs1689510 X O X O X VIT|8E−12|T1D| 9E−10|AA|3E−8| AST|2E−13|T1D| 5E−18|VIT| 3E−14|T1D| 1E−11|T1D| 3E−16|T1D| 2E−20|T1D| 3E−27| T1D|2E−25 rs12598357 X O O X CD|2E−11|IBD| 1E−21|T1D| 3E−13|T1D| 1E−8|IBD|2E−9 rs77150043 NA rs706778 X X X X O O O X O X X RA|1E−11|MS| 3E−11|AA|2E−12 rs4246905 O O O CD|1E−15|IBD| 3E−32|UC|6E−12| LEP|3E−21|CD| 3E−10|IBD|3E−8 rs2807264 NA rs1250563 X O O O O X IBD|3E−18|CD| 7E−14|PSOR| 7E−14|MS|4E−7| MS|2E−6| IBD|6E−9| MS|6E−9| CD|1E−30 rs62324212 X X O X X X X X X X NA rs11145763 X O O O UC|3E−19|IBD| 4E−56|CD| 4E−6|UC|5E−8| CD|1E−36|UC| 7E−6|AS|1E−6 rs2836882 O X O O O O AS|8E−20|UC| 2E−22|IBD| 4E−12| IBD|5E−48 rs602662 O X O IBD|1E−15|CD| 1E−15|CD| 2E−8|CD|7E−12 rs12863738 NA rs36051895 O O O UC|1E−6|UC| 2E−25|CD| 1E−13|IBD| 8E−45|CD|3E−9 rs4869313 O X X X O CD|1E−10| IBD|6E−13 rs2075184 O O O ADER|8E−18| CeD| 4E−9|CD| 2E−12|CeD| 1E−15|IBD| 3E−20 rs7672495 NA rs7042370 NA rs4676410 X X O O UC|2E−9| PSC|2E−9| IBD|3E−21 rs6689858 X X X X NA rs114846446 NA rs12232497 O O X X X X O IBD|4E−38|PBC| 8E−6|SLE| 7E−6|PBC|4E−9| SSC|7E−6|PBC| 2E−9|T1D| 2E−6|UC|5E−11| CD|5E−9| RA|9E−7 |CD|2E−9|UC| 1E−7|AST|1E−7| UC|3E−8|AST| 2E−16|T1D| 6E−13| AST|9E−11| AST|1E−8 rs62131887 X O O X O X O O X X NA rs34884278 O X X CD|2E−15|CD| 2E−9|IBD| 6E−22| CD|6E−22 rs7831697 NA rs12928404 X O O X CD|2E−11| IBD|1E−21| T1D|3E−13|T1D| 1E−8|IBD|2E−9 rs10988542 NA rs2738774 O O X X NA rs55705316 O O X X O UC|6E−17| UC|1E−8| CD|2E−14|UC| 1E−12|T1D| 5E−10|T1D| 2E−9|IBD| 7E−42| UC|1E−12| UC|8E−8 rs11839053 NA Table 2c: Detailed information for the lead loci with evidence of directions of effect heterogeneity across pAIDs. Abbreviations: SNP: rsID dbSNP 138; GENE: Candidate Gene Name (HGNC); REGION: Cytogenetic band; A1: alternative allele used in the logistic regression; pAIDs model: pAID(s) associated with this SNP based on the model search; BETA (SE) model: effect size and standard error of the SNP based on logistic regression combining cases from the diseases identified on the model search; pAID: the disease showing the opposite effect direction than that of the group of diseases identified by the subtype search; BETA (SE): effect size and standard error of the SNP for the disease found to have an opposite effect direction; P-value: disease-specific GWAS P-value.

TABLE 2c BETA(SE) CHR POS REGION SNP GENE A1 MAF HWE P INFO BETA(SE) pAID model pAIDs model 1 82237577 1p31.1 rs2066363 LPHN2 C 0.34 0.004 0.026 1.00 −0.49(0.17) CD 0.68(0.05) CVID|JIA 1 114303808 1p13.2 rs6679677 PTPN22 C 0.08 0.855 1.40E−04 0.99 −0.13(0.05) CD 0.59(0.06) THY|PS|T1D| JIA 1 206933517 1q32.1 rs55705316 IL10 T 0.14 0.715 2.88E−04 0.91 −0.13(0.05) T1D 0.21(0.04) PS|SLE|UC| CD 3 49572140 3p21.31 rs4625 DAG1 A 0.31 0.472 0.019 1.00 −0.08(0.04) AS 0.25(0.03) PS|CEL|UC| CD 4 4992367 4p16.2 rs7672495 CYTL1 T 0.18 0.162 0.042 0.96  0.34(0.17) PS 0.18(0.03) THY|AS|CEL| UC|T1D|JIA| CD 13 107063042 13q33.3 rs11839053 EFNB2 T 0.02 0.074 4.61E−03 0.93 −0.35(0.15) T1D 0.76(0.15) CVID|JIA 16 28340945 16p11.2 rs12598357 SBK1 A 0.39 0.257 0.013 0.90 −0.26(0.07) T1D 0.18(0.03) THY|AS|PS| CEL|UC|CD 16 28847246 16p11.2 rs12928404 ATXN2L T 0.38 0.325 8.94E−03 0.99 −0.25(0.07) T1D 0.17(0.03) UC|CD 21 40466570 21q22.2 rs2836882 PSMG1 G 0.27 0.112 0.038 0.98 −0.38(0.18) THY −0.21(0.04)  UC|CD

TABLE 2d Key summary attributes tabulated for the set of 27 GWS and 46 GWM lead loci GWM Category Description GWSGWM GWS only Total SNP-pAID pairs identified 146 77 69 Num of Pairs prev known 67 44 23 Num of Pairs novelly reported 79 33 46 Novel loci (no prev reported Al disease) 12 5 7 Loci assoc with 2 or more pAIDs 39 22 17 Loci assoc with at least one novel pAID 34 16 18 Pleiotropic Loci (>3 diseases) 25 11 14

TABLE 2e In silico replication results for the 12 putatively novel pAID associated loci reaching PMETA < 1 × 10⁻⁶. CHR SNP POS REGION P_META AI - - - D DATASET P_REP METHOD GENE GWS 1 rs2066363 82237577 1p31.1 8.38E−11 UC IBDG_UC 1.69E−02 SUM LPHN2 GWS 4 rs7660520 183745321 4q35.1 8.38E−11 PS CASP 3.65E−03 IMP TNM3 GWS 8 rs7831697 138136304 8q24.23 4.67E−07 RA RA_meta 1.02E−02 SUM 8q24.23 GWM 9 rs7042370 12785073 9p23 1.07E−07 CD NIDDK_IBD 2.69E−02 IMP LURAP1L GWM 16 rs77150043 50304249 16q12.1 5.99E−09 CD NIDDK_IBD 4.98E−04 IMP ADCY7 GWS 23 rs2807264 135665778 Xq26.3 1.25E−08 UC WT2_UC 4.66E−05 IMP CD40LG GWS 23 rs2807264 135665778 Xq26.3 1.25E−08 AS WT2_AS 9.54E−03 IMP CD40LG GWS 23 rs2807264 135665778 Xq26.3 1.25E−08 CD WT_CD 5.81E−04 IMP CD40LG GWS 23 rs12863738 136032127 Xq26.3 6.11E−08 UC WT2_UC 1.78E−03 IMP RBMX GWM 23 rs12863738 136032127 Xq26.3 6.11E−08 CeD CIDR_Celiac 3.72E−02 IMP RBMX GWM Table 3a: Significantly associated genes identified by Gene Based Association Testing (GBAT) Abbreviations: CHR: chromosome; nSNP: number of SNPs mapped to this gene; Start/Stop: gene start or stop position in build hg19; GENE: Candidate Gene Name (HGNC); PGBAT: P-value of the gene association test based on simulations; PBest SNP: Most significant Meta-analysis P-value of the SNPs mapping to this gene; DATASET: Best.SNP: lead SNP in the region with the lowest P-value; Test: Test statistic of the GBAT; q_value: FDR q-value.

TABLE 3a Chr Gene nSNPs Start Stop Test Pvalue Best.SNP SNP.pvalue q - - - value 1 C1orf141 124 67330446 67366808 1212. <1.00E−06 rs11209008 5.88E−10 0.00E+00 1 IL23R 146 67404756 67498238 2343. <1.00E−06 rs11209026 8.38E−11 0.00E+00 1 IL12RB2 122 67545634 67635171 995.1  2.00E−06 rs10889677 1.53E−10 1.94E−04 2 ATG16L1 142 23382495 233869059 2064. <1.00E−06 rs3792108 8.41E−11 0.00E+00 2 SAG 133 23388104 233920440 1668. <1.00E−06 rs3792108 8.41E−11 0.00E+00 3 USP4 63 49289997 49352519 866.6 <1.00E−06 rs6809216 8.39E−11 0.00E+00 3 GPX1 39 49369612 49370795 690.2 <1.00E−06 rs6809216 8.39E−11 0.00E+00 3 RHOA 60 49371582 49424530 1309. <1.00E−06 rs11711485 8.38E−11 0.00E+00 3 TCTA 40 49424642 49428913 969.7 <1.00E−06 rs11711485 8.38E−11 0.00E+00 3 AMT 40 49429214 49435016 969.8 <1.00E−06 rs11711485 8.38E−11 0.00E+00 3 NICN1 41 49434769 49441761 1046. <1.00E−06 rs11711485 8.38E−11 0.00E+00 3 DAG1 65 49482568 49548052 1345. <1.00E−06 rs4625 8.38E−11 0.00E+00 3 BSN 113 49566925 49683986 2144. <1.00E−06 rs4625 8.38E−11 0.00E+00 3 APEH 69 49686438 49695938 1426. <1.00E−06 rs9882740 8.43E−11 0.00E+00 3 MST1 66 49696391 49701099 1351. <1.00E−06 rs9882740 8.43E−11 0.00E+00 3 RNF123 73 49701993 49733966 1540. <1.00E−06 rs9882740 8.43E−11 0.00E+00 3 AMIGO3 53 49729968 49732127 1079. <1.00E−06 rs3197999 8.43E−11 0.00E+00 3 GMPPB 52 49733935 49736388 1036. <1.00E−06 rs3197999 8.43E−11 0.00E+00 3 IHPK1 72 49736731 49798977 1289. <1.00E−06 rs3197999 8.43E−11 0.00E+00 3 LOC389118 37 49810668 49812272 535.9 <1.00E−06 rs6802890 5.53E−07 0.00E+00 3 C3orf54 39 49815690 49817467 535.0  1.00E−06 rs6802890 5.53E−07 9.99E−05 3 UBA7 44 49817641 49826395 576.8 <1.00E−06 rs6802890 5.53E−07 0.00E+00 3 CAMKV 48 49870425 49882373 581.2  1.00E−06 rs6775384 5.64E−07 9.99E−05 5 LOC441108 193 13177457 131825958 1867. <1.00E−06 rs11741255 1.58E−09 0.00E+00 5 IRF1 132 13184668 131854326 1539. <1.00E−06 rs11741255 1.58E−09 0.00E+00 6 GABBR1 65 29677983 29708941 725.1 <1.00E−06 rs396660 1.39E−08 0.00E+00 6 MOG 69 29732787 29748128 758.3 <1.00E−06 rs396660 1.39E−08 0.00E+00 6 ZFP57 96 29748238 29756866 979.6 <1.00E−06 rs396660 1.39E−08 0.00E+00 6 HLA - - - F 107 29799095 29803052 1013. <1.00E−06 rs396660 1.39E−08 0.00E+00 6 HLA - - - G 37 29902734 29906878 350.6 <1.00E−06 rs2975033 5.93E−09 0.00E+00 6 HLA - - - A29.1 49 30018304 30085130 483.8 <1.00E−06 rs9366752 2.12E−09 0.00E+00 6 HLA - - - A 32 30018309 30021633 366.6 <1.00E−06 rs2256919 2.90E−07 0.00E+00 6 HCG9 38 30050870 30054156 406.4 <1.00E−06 rs2256919 2.90E−07 0.00E+00 6 ZNRD1 56 30137014 30140665 456.3 <1.00E−06 rs9366752 2.12E−09 0.00E+00 6 PPP1R11 54 30142910 30146087 450.2 <1.00E−06 rs9366752 2.12E−09 0.00E+00 6 RNF39 57 30146021 30151607 482.4 <1.00E−06 rs9366752 2.12E−09 0.00E+00 6 TR1M31 61 30178652 30188846 572.6 <1.00E−06 rs9366752 2.12E−09 0.00E+00 6 TRIM40 49 30212488 30224491 525.2 <1.00E−06 rs2021723 1.64E−07 0.00E+00 6 TRIM10 37 30227702 30236690 344.0 <1.00E−06 rs2021723 1.64E−07 0.00E+00 6 TRIM15 26 30238961 30248452 244.4 <1.00E−06 rs2021723 1.64E−07 0.00E+00 6 MUC21 44 31059463 31065654 410.8 <1.00E−06 rs13210132 4.47E−08 0.00E+00 6 C6orf15 198 31186978 31188311 1877. <1.00E−06 rs1265098 8.40E−11 0.00E+00 6 PSORS1C1 210 31130601 31215816 2023. <1.00E−06 rs1265098 8.40E−11 0.00E+00 6 CDSN 203 31190848 31196202 1943. <1.00E−06 rs1265098 8.40E−11 0.00E+00 6 PSORS1C2 205 31213289 31215106 1976. <1.00E−06 rs1265098 8.40E−41 0.00E+00 6 CCHCR1 212 31218194 31233994 2059.7 <1.00E−06 rs1265098 8.40E−11 0.00E+00 6 TCF19 206 31234281 31239971 2021.6 <1.00E−06 rs1265098 8.40E−11 0.00E+00 6 POU5F1 172 31240092 31246430 1549.0 <1.00E−06 rs1265098 8.40E−11 0.00E+00 6 HCG27 48 31273577 31279724 556.5 <1.00E−06 rs887464 1.66E−07 0.00E+00 6 HLA - - - C 59 31344507 31347834 703.9 <1.00E−06 rs2395471 3.50E−10 0.00E+00 6 HLA - - - B 61 31429627 31432968 1148.9 <1.00E−06 rs2596560 8.38E−11 0.00E+00 6 MICA 68 31479349 31491069 1330.9 <1.00E−06 rs2596560 8.38E−11 0.00E+00 6 HCP5 114 31538937 31541461 2395.3 <1.00E−06 rs2516403 8.42E−11 0.00E+00 6 MICB 146 31573833 31586880 2843.8 <1.00E−06 rs2516403 8.42E−11 0.00E+00 6 MCCD1 150 31604717 31605987 3011.4 <1.00E−06 rs2516403 8.42E−11 0.00E+00 6 BAT1 157 31605974 31618204 3054.4 <1.00E−06 rs2516403 8.42E−11 0.00E+00 6 ATP6V1G2 148 31620218 31622606 2873.6 <1.00E−06 rs2516403 8.42E−11 0.00E+00 6 NFKBIL1 142 31623350 31634585 2732.6 <1.00E−06 rs2516403 8.42E−11 0.00E+00 6 LTA 88 31648071 31650077 1418.8 <1.00E−06 rs1799964 1.72E−10 0.00E+00 6 TNF 87 31651328 31654091 1393.7 <1.00E−06 rs1799964 1.72E−10 0.00E+00 6 LTB 84 31656314 31658181 1360.6 <1.00E−06 rs1799964 1.72E−10 0.00E+00 6 LST1 87 31661949 31664665 1480.1 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 NCR3 90 31664650 31668741 1551.6 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 AIF1 64 31691011 31692777 1277.2 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 BAT2 62 31696428 31713533 1224.1 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 BAT3 39 31714783 31728456 848.7 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 APOM 26 31731649 31733966 681.5 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 C6orf47 25 31734053 31736528 662.0 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 BAT4 28 31737840 31741142 708.8 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 CSNK2B 29 31741635 31745822 739.0 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 LY6G5B 29 31746706 31748206 746.3 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 LY6G5C 28 31752439 31756120 738.4 <1.00E−06 rs1046089 8.38E−11 0.00E+00 6 BAT5 42 31762714 31779067 1082.1 <1.00E−06 rs1144708 8.38E−11 0.00E+00 6 LY6G6F 42 31782662 31786351 1063.2 <1.00E−06 rs1144708 8.38E−11 0.00E+00 6 LY6G6D 45 31791111 31793560 1053.2 <1.00E−06 rs1144708 8.38E−11 0.00E+00 6 LY6G6C 45 31794403 31797489 1053.2 <1.00E−06 rs1144708 8.38E−11 0.00E+00 6 C6orf25 44 31799139 31800830 1073.0 <1.00E−06 rs1144708 8.38E−11 0.00E+00 6 DDAH2 43 31802795 31806018 1071.8 <1.00E−06 rs1144708 8.38E−11 0.00E+00 6 CLIC1 42 31806336 31812320 1035.7 <1.00E−6  rs1144708 8.38E−11 0.00E+00 6 MSH5 50 31815752 31838431 1200.7 <1.00E−06 rs1144708 8.38E−11 0.00E+00 6 C6orf26 47 31838751 31840603 1127.0 <1.00E−06 rs1144708 8.38E−11 0.00E+00 6 C6orf27 49 31841349 31853087 1187.4 <1.00E−06 rs1144708 8.38E−11 0.00E+00 6 VARS 50 31853275 31871691 1225.4 <1.00E−06 rs1144708 8.38E−11 0.00E+00 6 LSM2 38 31873152 31882722 937.5 <1.00E−06 rs2227956 8.38E−11 0.00E+00 6 HSPA1L 31 31885374 31890814 667.0 <1.00E−06 rs2227956 8.38E−11 0.00E+00 6 HSPA1A 22 31891269 31893698 505.0 <1.00E−06 rs2227956 8.38E−11 0.00E+00 6 HSPA1B 42 31903490 31906010 699.4 <1.00E−06 rs2227956 8.38E−11 0.00E+00 6 C6orf48 47 31910671 31915520 772.3 <1.00E−06 rs2227956 8.38E−11 0.00E+00 6 NEU1 48 31934807 31938688 765.7 <1.00E−06 rs2227956 8.38E−11 0.00E+00 6 SLC44A4 47 31938948 31954802 701.6 <1.00E−06 rs497309 8.38E−11 0.00E+00 6 EHMT2 59 31955515 31973443 904.6 <1.00E−06 rs497309 8.38E−11 0.00E+00 6 ZBTB12 66 31975372 31977748 990.4 <1.00E−06 rs1270942 8.38E−11 0.00E+00 6 C2 65 32003472 32021427 1204.0 <1.00E−06 rs1270942 8.38E−11 0.00E+00 6 CFB 54 32021699 32027840 1012.7 <1.00E−06 rs1270942 8.38E−11 0.00E+00 6 RDBP 53 32027842 32034843 1000.9 <1.00E−06 rs1270942 8.38E−11 0.00E+00 6 SKIV2L 52 32034559 32045511 976.3 <1.00E−06 rs1270942 8.38E−11 0.00E+00 6 DOM3 52 32045566 32048011 976.3 <1.00E−06 rs1270942 8.38E−11 0.00E+00 6 STK19 - - - 1 52 32047624 32057202 976.3 <1.00E−06 rs1270942 8.38E−11 0.00E+00 6 C4A - - - 1 52 32057812 32078435 1008.3 <1.00E−06 rs1270942 8.38E−11 0.00E+00 6 C4B - - - 1 52 32057812 32078436 1008.3 <1.00E−06 rs1270942 8.38E−11 0.00E+00 6 STK19 - - - 2 26 32089495 32089939 640.1 <1.00E−06 rs1150758 8.38E−11 0.00E+00 6 C4A - - - 2 50 32090549 32111173 1117.4 <1.00E−06 rs1150754 8.38E−11 0.00E+00 6 C4B - - - 2 50 32090549 32111174 1117.4 <1.00E−06 rs1150754 8.38E−11 0.00E+00 6 CYP21A2 43 32114060 32117398 870.5 <1.00E−06 rs1150754 8.38E−11 0.00E+00 6 TNXB 69 32116910 32185129 1562.9 <1.00E−06 rs1150752 8.38E−11 0.00E+00 6 CREBL1 53 32191022 32203995 1228.9 <1.00E−06 rs1150752 8.38E−11 0.00E+00 6 FKBPL 43 32204461 32206045 1075.6 <1.00E−06 rs1150752 8.38E−11 0.00E+00 6 PRRT1 32 32224117 32227698 850.9 <1.00E−06 rs1269852 8.38E−11 0.00E+00 6 PPT2 29 32229278 32239430 759.7 <1.00E−06 rs1269852 8.38E−11 0.00E+00 6 EGFL8 21 32240382 32244040 542.0 <1.00E−06 rs3134603 8.38E−11 0.00E+00 6 A6PAT1 36 32243966 32253820 892.6 <1.00E−06 rs2267644 8.38E−11 0.00E+00 6 RNF5 36 32254139 32256548 892.6 <1.00E−06 rs2267644 8.38E−11 0.00E+00 6 AGER 39 32256723 32260001 953.1 <1.00E−06 rs2267644 8.38E−11 0.00E+00 6 PBX2 42 32260487 32265941 1000.9 <1.00E−06 rs2267644 8.38E−11 0.00E+00 6 GPSM3 48 32266520 32271278 1124.8 <1.00E−06 rs2267644 8.38E−11 0.00E+00 6 NOTCH4 55 32270597 32299822 1373.4 <1.00E−06 rs2267644 8.38E−11 0.00E+00 6 C6orf10 70 32368452 32447634 2440.6 <1.00E−06 rs10947262 8.38E−11 0.00E+00 6 BTNL2 53 32470490 32482878 1992.5 <1.00E−06 rs10947262 8.38E−11 0.00E+00 6 HLA - - - DRA 36 32515624 32520802 1388.6 <1.00E−06 rs10947262 8.38E−11 0.00E+00 6 HLA - - - 27 32654524 32665540 997.6 <1.00E−06 rs17425622 8.38E−11 0.00E+00 6 HLA - - - 46 32713160 32719407 1745.9 <1.00E−06 rs1063355 8.38E−11 0.00E+00 6 HLA - - - 44 32735634 32742444 1461.6 <1.00E−06 rs1063355 8.38E−11 0.00E+00 6 HLA - - - 52 32817140 32823199 1401.6 <1.00E−06 rs10807113 8.38E−11 0.00E+00 6 HLA - - - DOB 206 32888517 32892803 5053.7 <1.00E−06 rs1015166 8.38E−11 0.00E+00 6 TAP2 206 32897587 32914525 4945.3 <1.00E−06 rs1015166 8.38E−11 0.00E+00 6 PSMB8 200 32916471 32920690 4794.5 <1.00E−06 rs1015166 8.38E−11 0.00E+00 6 TAP1 202 32920963 32929726 4879.4 <1.00E−06 rs1015166 8.38E−11 0.00E+00 6 PSMB9 195 32929915 32935606 4766.9 <1.00E−06 rs1015166 8.38E−11 0.00E+00 6 HLA - - - DMB 55 33010392 33016795 734.5 <1.00E−06 rs241407 8.38E−11 0.00E+00 6 HLA - - - DMA 58 33024372 33028831 669.0 <1.00E−06 rs3101942 8.38E−11 0.00E+00 6 BRD2 125 33044414 33057260 1382.2 <1.00E−06 rs9501239 8.40E−11 0.00E+00 6 HLA - - - DOA 103 33079937 33085367 1125.6 <1.00E−06 rs378352 5.98E−10 0.00E+00 6 HLA - - - DPA1 44 33140771 33149356 778.8 <1.00E−06 rs2301226 8.38E−11 0.00E+00 6 HLA - - - DPB1 47 33151737 33162954 824.8 <1.00E−06 rs2301226 8.38E−11 0.00E+00 6 COL11A2 94 33238446 33268223 958.9  1.00E−06 rs4713610 1.76E−09 9.99E−05 6 WDR46 26 33354862 33364969 330.6  2.00E−06 rs3106189 1.14E−06 1.94E−04 9 TNFSF15 113 11659143 116608229 1270.5 <1.00E−06 rs4246905 9.45E−09 0.00E+00 9 GPSM1 75 13834872 138372493 1011.5 <1.00E−06 rs10870077 3.36E−08 0.00E+00 9 DNL 83 13837617 138378062 1077.0  1.00E−06 rs10870077 3.36E−08 9.99E−05 9 CARD9 92 13837822 138387939 1173.8 <1.00E−06 rs10870077 3.36E−08 0.00E+00 9 SNAPC4 118 13838984 138412710 1427.1 <1.00E−06 rs10870077 3.36E−08 0.00E+00 9 SDCCAG3 120 13841619 138424875 1435.4  1.00E−06 rs10870077 3.36E−08 9.99E−05 9 PMPCA 116 13842493 138438034 1444.6 <1.00E−06 rs10870077 3.36E−08 0.00E+00 9 INPP5E 108 13844289 138454077 1154.8 <1.00E−06 rs4567159 5.36E−08 0.00E+00 9 SEC16A 114 13845436 138497328 1033.0  1.00E−06 rs4266763 6.08E−08 9.99E−05 10 IL2RA 183 6093511 6144278 978.1 <1.00E−06 rs706778 6.34E−09 0.00E+00 10 NKX2 - - - 3 155 10128267 101286270 2039.1 <1.00E−06 rs1332099 9.06E−11 0.00E+00 11 IGF2 98 2106922 2127409 1110.8 <1.00E−06 rs3842727 8.38E−11 0.00E+00 11 IGF2AS 79 2118312 2126470 1061.4 <1.00E−06 rs3842727 8.38E−11 0.00E+00 11 INS - - - IGF2 107 2124431 2139015 1257.6 <1.00E−06 rs3842727 8.38E−11 0.00E+00 11 INS 101 2137584 2139015 1253.3 <1.00E−06 rs3842727 8.38E−11 0.00E+00 11 TH 125 2141734 2149611 1376.9 <1.00E−06 rs3842727 8.38E−11 0.00E+00 12 LRRK2 605 38905079 39049353 4273.4 <1.00E−06 rs17466626 3.24E−10 0.00E+00 12 SILV 47 54634155 54646093 377.6 <1.00E−06 rs772921 6.01E−09 0.00E+00 12 CDK2 47 54646822 54652835 411.1 <1.00E−06 rs772921 6.01E−09 0.00E+00 12 RAB5B 51 54654128 54674755 502.5 <1.00E−06 rs772921 6.01E−09 0.00E+00 12 SUOX 46 54677309 54685576 502.1 <1.00E−06 rs772921 6.01E−09 0.00E+00 12 IKZF4 49 54700955 54718486 670.4 <1.00E−06 rs772921 6.01E−09 0.00E+00 12 RPS26 34 54721952 54724274 468.8 <1.00E−06 rs772921 6.01E−09 0.00E+00 12 LOC728937 34 54722190 54724271 468.8 <1.00E−06 rs772921 6.01E−09 0.00E+00 12 ERBB3 45 54760158 54783395 423.0 <1.00E−06 rs705704 1.24E−08 0.00E+00 15 SMAD3 255 65145248 65274587 1367.5 <1.00E−06 rs17228058 8.85E−11 0.00E+00 16 LOC390688 1 28332524 28333958 27.6 <1.00E−06 rs149299 1.49E−07 0.00E+00 16 LOC440350- 12 28376192 28389260 302.8 <1.00E−06 rs151181 7.45E−08 0.00E+00 16 CLN3 19 28396100 28411124 449.3 <1.00E−06 rs12446550 6.39E−08 0.00E+00 16 APOB48R 26 28413493 28417783 552.9 <1.00E−06 rs12446550 6.39E−08 0.00E+00 16 IL27 28 28418183 28425656 595.2 <1.00E−06 rs12446550 6.39E−08 0.00E+00 16 NUPR1 45 28456162 28457996 821.3 <1.00E−06 rs12446550 6.39E−08 0.00E+00 16 CCDC101 51 28472757 28510610 854.1 <1.00E−06 rs12446550 6.39E−08 0.00E+00 16 SULT1A2 41 28510766 28515892 642.4 <1.00E−06 rs3859172 7.54E−08 0.00E+00 16 SULT1A1 32 28524416 28542367 496.5 <1.00E−06 rs1968752 8.74E−08 0.00E+00 16 LOC440350- 8 28563411 28576505 167.4 <1.00E−06 rs1968752 8.74E−08 0.00E+00 16 ATXN2L 32 28741914 28756059 677.2  2.00E−06 rs8049439 4.40E−07 1.94E−04 16 TUFM 35 28761232 28765230 721.6  1.00E−06 rs8049439 4.40E−07 9.99E−05 16 SH2B1 44 28782814 28793027 862.8  2.00E−06 rs8049439 4.40E−07 1.94E−04 16 ATP2A1 46 28797309 28823331 810.0  1.00E−06 rs12928404 5.68E−07 9.99E−05 16 RABEP2 45 28823242 28844033 601.1  2.00E−06 rs8055982 7.91E−07 1.94E−04 16 SNX20 73 49264386 49272667 1228.7 <1.00E−06 rs11649521 8.38E−11 0.00E+00 16 NOD2 82 49288550 49324488 1509.8 <1.00E−06 rs11649521 8.38E−11 0.00E+00 16 CYLD 144 49333461 49393347 1889.9 <1.00E−06 rs11649521 8.38E−11 0.00E+00 17 ZPBP2 68 35277980 35287675 892.7 <1.00E−06 rs12232497 2.71E−07 0.00E+00 19 LOC126147 64 53856475 53868076 634.9  1.00E−06 rs602662 5.31E−08 9.99E−05

TABLE 3b Expression of genes associated with pAIDs are enriched in immune tissues. Mean ES-values and P-values of the TGSEA Wilcoxon rank sum test results for the pAID-associated gene set. Wilcoxon Test KS Test (per tissue/cell) (per tissue/cell) Across all GBAT GWS Non- Non- tissues/cells Genes Immune Immune Immune Immune Mean ES values all 2.982 1.089 3.06 1.277 noMHC 0.448 0.099 0.561 0.068 2-sided KS Test all 3.96E−14 5.04E−12 (P-value) noMHC 1.33E−14 3.47E−13 2-sided Wilcoxon all 4.99E−17 3.20E−15 Test (P-value) noMHC 1.77E−15 7.25E−15

TABLE 3c ImmGen (murine) cell lines included by cell lineage and developmental stage. Immgen Catalog Name Type Plot_name Organ SC LT34F BM StemCell StemCell 1 BM SC_LTSL_BM StemCell StemCell_2 BM SC_STSL_BM StemCell StemCell_3 BM SC_LTSL_FL StemCell StemCell_4 FL SC_STSL_FL StemCell StemCell_5 FL SC_MPP34F_BM StemCell StemCell_6 BM SC_ST34F_BM StemCell StemCell_7 BM SC_CMP_BM StemCell StemCell_8 BM SC_MEP_BM StemCell StemCell_9 BM SC_GMP_BM StemCell StemCell_10 BM SC_CDP_BM StemCell StemCell_11 BM SC_MDP_BM StemCell StemCell_12 BM DC_4._Sp DC Dendritic_15 SPL DC_8._Sp DC Dendritic_16 SPL DC_8.4.11b._Sp DC Dendritic_17 SPL DC_8.4.11b._Sp.1 DC Dendritic_18 SPL DC_pDC_8._Sp DC Dendritic_19 SPL DC_pDC_8._Sp.1 DC Dendritic_20 SPL DC_4._SLN DC Dendritic_21 LN DC_8._SLN DC Dendritic_22 LN DC_8.4.11b._SLN DC Dendritic_23 LN DC_8.4.11b._SLN.1 DC Dendritic_24 LN DC_pDC_8._SLN DC Dendritic_25 LN DC_IIhilang.103.11blo_SLN DC Dendritic_26 LN DC_IIhilang.103.11b._SLN DC Dendritic_27 LN DC_IIhilang.103.11blo_SLN.1 DC Dendritic_28 LN DC_IIhilang.103.11b._SLN.1 DC Dendritic_29 LN DC_4._MLN DC Dendritic_30 MLN DC_8._MLN DC Dendritic_31 MLN DC_8.4.11b._MLN DC Dendritic_32 MLN DC_8.4.11b._MLN.1 DC Dendritic_33 MLN DC_pDC_8._MLM DC Dendritic_34 MLN DC_LC_Sk DC Dendritic_35 Skin DC_103.11b._Lv DC Dendritic_36 LV DC_103.11b._Lv.1 DC Dendritic_37 LV DC_103.11b._LuLN DC Dendritic_38 LuLN DC_103.11b._LuLN.1 DC Dendritic_39 LuLN DC_103.11b.24.Lu DC Dendritic_40 Lu DC_103.11b._Lu DC Dendritic_41 Lu DC_103.11b._PolyIC_Lu DC Dendritic_42 Lu DC_103.11b._PolyIC_Lu.1 DC Dendritic_43 Lu DC_103.11b.F4.80lo_Kd DC Dendritic_44 kidney DC_103.11b._SI DC Dendritic_45 sm intest DC_103.11b._SI.1 DC Dendritic_46 sm intest Mo_6C.II._BM Monocytes Monocytes_49 BM Mo_6C.II_BM.1 Monocytes Monocytes_50 BM Mo_6C.II._BI Monocytes Monocytes_51 BI Mo_6C.II._BI.1 Monocytes Monocytes_52 BI Mo_6C.II._BI.2 Monocytes Monocytes_53 BI Mo_6C.II._BI.3 Monocytes Monocytes_54 BI Mo_6C.IIint_BI Monocytes Monocytes_55 BI Mo_6C.II._LN Monocytes Monocytes_56 LN MLP_BM StemCell StemCell_57 BM MLP_FL StemCell StemCell_58 FL proB_CLP_BM B_Dev B_Dev_59 BM proB_FrA_BM B_Dev B_Dev_60 BM proB_FrBC_BM B_Dev B_Dev_61 BM preB_FrC_BM B_Dev B_Dev_62 BM preB_FrD_BM B_Dev B_Dev_63 BM B_FrE_BM B_Dev B_Dev_64 BM proB_CLP_FL B_Dev B_Dev_65 FL proB_FrA_FL B_Dev B_Dev_66 FL proB_FrBC_FL B_Dev B_Dev_67 FL pre-B_FrD_PL B_Dev B_Dev_68 FL B_FrE_FL B_Dev B_Dev_69 FL B_T1_Sp B_Dev B_Dev_70 SPL B_T2_Sp B_Dev B_Dev_71 SPL B_T3_Sp B_Dev B_Dev_72 SPL B_Fo_Sp B_Mature B_Mature_73 SPL B_GC_Sp B_Mature B_Mature_74 SPL B_MZ_Sp B_Mature B_Mature_75 SPL B1a_Sp B_Mature B_Mature_76 SPL B_FrF_BM B_Mature B_Mature_77 BM B_Fo_MLN B_Mature B_Mature_78 MLN B_Fo_LN B_Mature B_Mature_79 LN B_Fo_PC B_Mature B_Mature_80 PerC B1b_PC B_Mature B_Mature_81 PerC B1a_PC B_Mature B_Mature_82 PerC MF_BM Macrophages Macrophages_83 BM MF_RP_Sp Macrophages Macrophages_84 SPL MF_Lu Macrophages Macrophages_85 Lu MF_103.11b.24._Lu Macrophages Macrophages_86 Lu MF_II.480lo_PC Macrophages Macrophages_87 PC MF_103.11b._SI Macrophages Macrophages_88 SI MF_11cloSer_SI Macrophages Macrophages_89 SI MF_II.480hi_PC Macrophages Macrophages_92 PC MF_Microglia_CNS Macrophages Macrophages_93 CNS BEC_SLN Stromal Stromal_213 SLN St_31.38.44_SLN Stromal Stromal_214 SLN GN_BM Neutrop Neutrophils_9 BM GN_BI Neutrop Neutrophils_9 BI GN_Arth_BM Neutrophils Neutrophils_100 BM GN_Arth_SynF Neutrophils Neutrophils_101 SynF GN_UrAc_PC Neutrophils Neutrophils_102 PC NK_Sp NK NK_104 SPL NK_46CI._Sp NK NK_105 SPL NK_49CI._Sp.1 NK NK_106 SPL NK_49H._Sp NK NK_107 SPL NK_49H._Sp.1 NK NK_108 SPL preT_ETP_Th T_Dev T_Dev_116 Th preT_ETP.2A_Th T_Dev T_Dev_117 Th preT_DN2_Th T_Dev T_Dev_118 Th preT_DN2A_Th T_Dev T_Dev_119 Th preT_DN2B_Th T_Dev T_Dev_120 Th preT_DN2.3_Th T_Dev T_Dev_121 Th preT_DN3A_Th T_Dev T_Dev_122 Th preT_DN3B_Th T_Dev T_Dev_123 Th preT_DN3.4_Th T_Dev T_Dev_124 Th T_DN4_Th T_Dev T_Dev_125 Th T_ISP_Th T_Dev T_Dev_126 Th T_DP_Th T_Dev T_Dev_127 Th T_DPbl_Th T_Dev T_Dev_128 Th T_DPsm_Th T_Dev T_Dev_129 Th T_DP69._Th T_Dev T_Dev_130 Th T_4.8int_Th T_Dev T_Dev_131 Th T_4SP69._Th T_CD4 T_CD4_132 Th T_4SP24int_Th T_CD4 T_CD4_133 Th T_4SP24._Th T_CD4 T_CD4_134 Th T_4int8._Th T_Dev T_Dev_135 Th T_8SP69._Th T_CD8 T_CD8_136 Th T_8SP24int_Th T_CD8 T_CD8_137 Th T_8SP24._Th T_CD8 T_CD8_138 Th T_4Nve_Sp T_CD4 T_CD4_139 SPL T_4Mem_Sp T_CD4 T_CD4_140 SPL T_4Mem44h62l_Sp T_CD4 T_CD4_141 SPL T_4Nve_LN T_CD4 T_CD4_142 LN T_4Mem_LN T_CD4 T_CD4_143 LN T_4Mem44h62l_LN T_CD4 T_CD4_144 LN T_4Nve_PP T_CD4 T_CD4_145 PP T_4Nve_MLN T_CD4 T_CD4_146 MLN T_4_LN_BDC T_CD4 T_CD4_147 BDC T_4_PLN_BDC T_CD4 T_CD4_148 BDC T_4_Pa_BDC T_CD4 T_CD4_149 BDC T_4FP3._Sp T_CD4 T_CD4_150 SPL T_4FP3.25._Sp T_CD4 T_CD4_151 SPL T_4FP3.25._AA T_CD4 T_CD4_152 AA T_4FP3.25._LN T_CD4 T_CD4_153 LN T_8Nve_Sp T_CD8 T_CD8_154 SPL T_8Mem_Sp T_CD8 T_CD8_155 SPL T_SNve_LN T_CD8 T_CDS_156 LN T_8Mem_LN T_CD8 T_CD8_157 LN T_8Nve_PP T_CD8 T_CD8_158 PP T_8Nve_MLN T_CD8 T_CD8_159 MLN NKT_44.NK1_1._Th NK_T NK_T_176 Th NKT_44.NK1_1._Th.1 NK_T NK_T_177 Th NKT_44.NK1_1._Th.2 NK_T NK_T_178 Th NKT_4._Sp NK_T NK_T_179 SPL NKT_4._Sp.1 NK_T NK_T_180 SPL NKT_4._Lv NK_T NK_T_181 Lv NKT_4._Lv.1 NK_T NK_T_182 Lv Tgd_Th T_gd T_gd_183 Th Tgd_vg2.24ahi_Th T_gd T_gd_186 Th Tgd_vg2.24ahi_e17_Th T_gd T_gd_187 Th Tgd_vg3.24ahi_e17_Th T_gd T_gd_188 Th Tgd_vg5.24ahi_Th T_gd T_gd_189 Th Tgd_vg1.vd6.24alo_Th T_gd T_gd_190 Th Tgd_vg1.vd6.24alo_Th.1 T_gd T_gd_191 Th Tgd_vg2.24alo_Th T_gd T_gd_192 Th Tgd_vg3.24alo_e17_Th T_gd T_gd_193 Th Tgd_Sp T_gd T_gd_194 SPL Tgd_vg2._Sp T_gd T_gd_195 SPL Tgd_vg2._act_Sp T_gd T_gd_196 SPL Tgd_vg2._Sp.1 T_gd T_gd_197 SPL Tgd_vg2._act_Sp.1 T_gd T_gd_198 SPL Tgd_vg5._IEL T_gd T_gd_201 IEL Tgd_vg5._IEL.1 T_gd T_gd_202 IEL Tgd_vg5._act_IEL T_gd T_gd_203 IEL Tgd_vg5._act_IEL.1 T_gd T_gd_204 IEL Ep_MEChi_Th Stromal Stromal_205 Th Fi_MTS15._Th Stromal Stromal_206 Th Fi_Sk Stromal Stromal_207 Skin FRC_MLN Stromal Stromal_208 MLN FRC_SLN Stromal Stromal_209 SLN LEC_MLN Stromal Stromal_210 MLN LEC_SLN Stromal Stromal_211 SLN BEC_MLN Stromal Stromal_212 MLN BEC_SLN Stromal Stromal_213 SLN St_31.38.44._SLN Stroma Stromal_214 SLN

TABLE 4a Significant pAID pairs identified by genome-wide pairwise sharing analysis. pAIDs GPS P-value MHC removed GPS P-value CEL-T1D 3.44E−05 8.02E−01 CVID-JIA 6.88E−05 7.30E−05 UC-T1D 2.26E−04 3.73E−01 T1D-JIA 2.76E−04 1.31E−02 UC-JIA 3.15E−04 9.83E−01 CEL-UC 4.99E−04 8.17E−01 CD-UC 2.36E−03 7.32E−04 CEL-JIA 8.19E−04 3.28E−02

TABLE 4b Significant autoimmune disease pairs identified by locus-specific pairwise sharing analysis. Pair Zstat P-value Adj P-value SJO-SSC 11.53 9.05E−31 1.38E−28 PBC-SJO 7.62 2.52E−14 3.86E−12 T1D-JIA 5.75 9.13E−09 1.40E−06 CEL-JIA 5.74 9.40E−09 1.44E−06 CVID-JIA 5.67 1.47E−08 2.25E−06 MS-PBC 5.33 1.01E−07 1.54E−05 CEL-THY 5.25 1.49E−07 2.28E−05 T1D-PBC 5.21 1.88E−07 2.88E−05 CVID-THY 5.12 3.08E−07 4.71E−05 PBC-SSC 5.10 3.36E−07 5.14E−05 JIA-PBC 4.90 9.46E−07 1.45E−04 UC-CD 4.82 1.41E−06 2.15E−04 CEL-RA 4.67 2.98E−06 4.56E−04 CEL-PSC 4.51 6.50E−06 9.94E−04 SLE-THY 4.51 6.59E−06 1.01E−03 SLE-SJO 4.50 6.65E−06 1.02E−03 PSC-THY 4.40 1.09E−05 1.66E−03 T1D-VIT 4.38 1.18E−05 1.81E−03 SLE-SSC 4.19 2.75E−05 4.20E−03 PS-JIA 4.15 3.39E−05 5.19E−03 VIT-THY 4.10 4.12E−05 6.31E−03 AS-JIA 4.09 4.30E−05 6.58E−03 T1D-AA 3.89 9.96E−05 1.52E−02 CEL-PBC 3.88 1.06E−04 1.63E−02 CEL-SJO 3.78 1.59E−04 2.43E−02 RA-THY 3.74 1.87E−04 2.86E−02 PBC-RA 3.68 2.30E−04 3.51E−02 AA-VIT 3.66 2.56E−04 3.92E−02 **Note that due to limited data available across the MHC, candidate genes in the extended MHC were not included in this analysis

TABLE 5 MicroRNA target (a) and transcription factor (b) consensus binding site target gene set enrichment analysis. Target Seq (Known TF) TF_ID Enrichment Statistics hsa_GGGCGGR_V$SP1_Q6 DB_ID = 2452 C = 2891; O = 45; E = 11.93; R = 3.77; rawP = 5.42e−15; adjP = 2.30e−12 hsa_TGGAAA_V$NFAT_Q4_01 DB_ID = 2437 C = 1871; O = 31; E = 7.72; R = 4.01; rawP = 4.02e−11; adjP = 8.54e−09 hsa_V$NFKB_C DB_ID = 1992 C = 262; O = 13; E = 1.08; R = 12.02; rawP = 8.64e−11; adjP = 1.03e−08 hsa_CTTTGT_V$LEF1_Q2 DB_ID = 2428 C = 1939; O = 31; E = 8.00; R = 3.87; rawP = 9.71e−11; adjP = 1.03e−08 hsa_RYTTCCTG_V$ETS2_B DB_ID = 2415 C = 1074; O = 21; E = 4.43; R = 4.74; rawP = 4.47e−09; adjP = 3.80e−07 hsa_V$TEF1_Q6 DB_ID = 2212 C = 222; O = 10; E = 0.92; R = 10.91; rawP = 3.42e−08; adjP = 2.42e−06 hsa_TTANTCA_UNKNOWN DB_ID = 2372 C = 937; O = 18; E = 3.87; R = 4.65; rawP = 7.91e−08; adjP = 4.80e−06 hsa_V$NFKAPPAB_01 DB_ID = 1874 C = 250; O = 10; E = 1.03; R = 9.69; rawP = 1.04e−07; adjP = 5.53e−06 hsa_V$MYOD_Q6_01 DB_ID = 2305 C = 254; O = 10; E = 1.05; R = 9.54; rawP = 1.20e−07; adjP = 5.67e−06 hsa_CAGCTG_V$AP4_Q5 DB_ID = 2403 C = 1502; O = 22; E = 6.20; R = 3.55; rawP = 2.99e−07; adjP = 1.27e−05 hsa_V$GATA1_02 DB_ID = 1930 C = 241; O = 9; E = 0.99; R = 9.05; rawP = 8.12e−07; adjP = 3.14e−05 hsa_V$NFAT_Q6 DB_ID = 2050 C = 245; O = 9; E = 1.01; R = 8.90; rawP = 9.31e−07; adjP = 3.30e−05 hsa_V$AML1_01 DB_ID = 2032 C = 261; O = 9; E = 1.08; R = 8.35; rawP = 1.57e−06; adjP = 4.65e−05 hsa_V$AML1_Q6 DB_ID = 2244 C = 261; O = 9; E = 1.08; R = 8.35; rawP = 1.57e−06; adjP = 4.65e−05 hsa_GGGTGGRR_V$PAX4_03 DB_ID = 2445 C = 1278; O = 19; E = 5.27; R = 3.60; rawP = 1.64e−06; adjP = 4.65e−05 hsa_GGGAGGRR_V$MAZ_Q6 DB_ID = 2430 C = 2250; O = 26; E = 9.29; R = 2.80; rawP = 2.08e−06; adjP = 5.53e−05 hsa_TGAYRTCA_V$ATF3_Q6 DB_ID = 2406 C = 531; O = 12; E = 2.19; R = 5.48; rawP = 2.45e−06; adjP = 6.12e−05 hsa_V$AHR_Q5 DB_ID = 2263 C = 209; O = 8; E = 0.86; R = 9.27; rawP = 2.80e−06; adjP = 6.61e−05 hsa_CAGGTG_V$E12_Q6 DB_ID = 2409 C = 2450; O = 27; E = 10.11; R = 2.67; rawP = 3.14e−06; adjP = 6.67e−05 hsa_TCCCRNNRTGC_UNKNOWN DB_ID = 2364 C = 211; O = 8; E = 0.87; R = 9.19; rawP = 3.01e−06; adjP = 6.67e−05 hsa_GATAAGR_V$GATA_C DB_ID = 2419 C = 290; O = 9; E = 1.20; R = 7.52; rawP = 3.71e−06; adjP = 7.51e−05 hsa_YGCGYRCGC_UNKNOWN DB_ID = 2389 C = 314; O = 9; E = 1.30; R = 6.94; rawP = 7.04e−06; adjP = 0.0001 hsa_TATAAA_V$TATA_01 DB_ID = 2456 C = 1276; O = 18; E = 5.27; R = 3.42; rawP = 6.41e−06; adjP = 0.0001 hsa_AACTTT_UNKNOWN DB_ID = 1851 C = 1859; O = 22; E = 7.67; R = 2.87; rawP = 9.45e−06; adjP = 0.0001 hsa_V$ISRE_01 DB_ID = 2029 C = 246; O = 8; E = 1.02; R = 7.88; rawP = 9.26e−06; adjP = 0.0001 hsa_V$YY1_Q6 DB_ID = 2268 C = 238; O = 8; E = 0.98; R = 8.14; rawP = 7.28e−06; adjP = 0.0001 hsa_V$NRF1_Q6 DB_ID = 2193 C = 245; O = 8; E = 1.01; R = 7.91; rawP = 8.99e−06; adjP = 0.0001 hsa_CACGTG_V$MYC_Q2 DB_ID = 2434 C = 1015; O = 16; E = 4.19; R = 3.82; rawP = 5.48e−06; adjP = 0.0001 hsa_V$COREBINDINGFACTOR_Q6 DB_ID = 2221 C = 266; O = 8; E = 1.10; R = 7.29; rawP = 1.63e−05; adjP = 0.0002 hsa_ACTAYRNNNCCCR_UNKNOWN DB_ID = 1928 C = 444; O = 10; E = 1.83; R = 5.46; rawP = 1.77e−05; adjP = 0.0002 hsa_TTGTTT_V$FOXO4_01 DB_ID = 2416 C = 2037; O = 23; E = 8.41; R = 2.74; rawP = 1.24e−05; adjP = 0.0002 hsa_V$USF_C DB_ID = 1999 C = 275; O = 8; E = 1.14; R = 7.05; rawP = 2.07e−05; adjP = 0.0003 hsa_V$EGR_Q6 DB_ID = 2283 C = 273; O = 8; E = 1.13; R = 7.10; rawP = 1.96e−05; adjP = 0.0003 hsa_V$CREB_Q4_01 DB_ID = 2294 C = 209; O = 7; E = 0.86; R = 8.11; rawP = 2.81e−05; adjP = 0.0004 hsa_GCANCTGNY_V$MYOD_Q6 DB_ID = 2435 C = 913; O = 14; E = 3.77; R = 3.72; rawP = 2.91e−05; adjP = 0.0004 hsa_TGGNNNNNNKCCAR_UNKNOWN DB_ID = 2368 C = 411; O = 9; E = 1.70; R = 5.31; rawP = 5.81e−05; adjP = 0.0006 hsa_V$NFKB_Q6_01 DB_ID = 2259 C = 231; O = 7; E = 0.95; R = 7.34; rawP = 5.30e−05; adjP = 0.0006 hsa_TGACGTCA_V$ATF3_Q6 DB_ID = 2405 C = 230; O = 7; E = 0.95; R = 7.37; rawP = 5.16e−05; adjP = 0.0006 hsa_TGTTTGY_V$HNF3_Q6 DB_ID = 2423 C = 733; O = 12; E = 3.03; R = 3.97; rawP = 5.91e−05; adjP = 0.0006 hsa_V$ZF5_01 DB_ID = 2217 C = 234; O = 7; E = 0.97; R = 7.25; rawP = 5.75e−05; adjP = 0.0006 hsa_YTTCCNNNGGAMR_UNKNOWN DB_ID = 2398 C = 52; O = 4; E = 0.21; R = 18.64; rawP = 6.51e−05; adjP = 0.0007 hsa_V$USF2_Q6 DB_ID = 2224 C = 249; O = 7; E = 1.03; R = 6.81; rawP = 8.48e−05; adjP = 0.0007 hsa_GTGACGY_V$E4F1_Q6 DB_ID = 2412 C = 646; O = 11; E = 2.67; R = 4.13; rawP = 8.54e−05; adjP = 0.0007 hsa_V$MYC_Q2 DB_ID = 2274 C = 182; O = 6; E = 0.75; R = 7.99; rawP = 0.0001; adjP = 0.0007 hsa_V$CREBP1_Q2 DB_ID = 1970 C = 254; O = 7; E = 1.05; R = 6.68; rawP = 9.60e−05; adjP = 0.0007 hsa_V$YY1_01 DB_ID = 1879 C = 245; O = 7; E = 1.01; R = 6.92; rawP = 7.67e−05; adjP = 0.0007 hsa_V$TAL1BETAE47_01 DB_ID = 1882 C = 246; O = 7; E = 1.02; R = 6.89; rawP = 7.86e−05; adjP = 0.0007 hsa_V$HMGIY_Q6 DB_ID = 2243 C = 248; O = 7; E = 1.02; R = 6.84; rawP = 8.27e−05; adjP = 0.0007 hsa_RCGCANGCGY_V$NRF1_Q6 DB_ID = 2441 C = 894; O = 13; E = 3.69; R = 3.52; rawP = 9.60e−05; adjP = 0.0007 hsa_RACCACAR_V$AML_Q6 DB_ID = 2401 C = 255; O = 7; E = 1.05; R = 6.65; rawP = 9.83e−05; adjP = 0.0007 hsa_V$AREB6_03 DB_ID = 2080 C = 253; O = 7; E = 1.04; R = 6.70; rawP = 9.36e−05; adjP = 0.0007 hsa_V$AML_Q6 DB_ID = 2253 C = 261; O = 7; E = 1.08; R = 6.50; rawP = 0.0001; adjP = 0.0007 hsa_V$HOXA4_Q2 DB_ID = 2183 C = 266; O = 7; E = 1.10; R = 6.38; rawP = 0.0001; adjP = 0.0007 hsa_V$FXR_Q3 DB_ID = 2177 C = 113; O = 5; E = 0.47; R = 10.72; rawP = 0.0001; adjP = 0.0007 hsa_V$ELF1_Q6 DB_ID = 2240 C = 238; O = 7; E = 0.98; R = 7.13; rawP = 6.39e−05; adjP = 0.0007 hsa_V$IRF7_01 DB_ID = 2110 C = 250; O = 7; E = 1.03; R = 6.78; rawP = 8.69e−05; adjP = 0.0007 hsa_V$CREBP1CJUN_01 DB_ID = 1867 C = 258; O = 7; E = 1.06; R = 6.57; rawP = 0.0001; adjP = 0.0007 hsa_V$TAL1BETAITF2_01 DB_ID = 1887 C = 253; O = 7; E = 1.04; R = 6.70; rawP = 9.36e−05; adjP = 0.0007 hsa_V$CREB_01 DB_ID = 1865 C = 261; O = 7; E = 1.08; R = 6.50; rawP = 0.0001; adjP = 0.0007 hsa_V$GATA1_04 DB_ID = 1932 C = 242; O = 7; E = 1.00; R = 7.01; rawP = 7.10e−05; adjP = 0.0007 hsa_GCTNWTTGK_UNKNOWN DB_ID = 2247 C = 299; O = 7; E = 1.23; R = 5.67; rawP = 0.0003; adjP = 0.0021 hsa_MGGAAGTG_V$GABP_B DB_ID = 2418 C = 744; O = 11; E = 3.07; R = 3.58; rawP = 0.0003; adjP = 0.0021 hsa_SYATTGTG_UNKNOWN DB_ID = 2360 C = 231; O = 6; E = 0.95; R = 6.29; rawP = 0.0004; adjP = 0.0027 hsa_V$NFKAPPAB65_01 DB_ID = 1871 C = 235; O = 6; E = 0.97; R = 6.19; rawP = 0.0005; adjP = 0.0033 hsa_V$STAT5A_01 DB_ID = 2112 C = 243; O = 6; E = 1.00; R = 5.98; rawP = 0.0005; adjP = 0.0033 hsa_V$HNF4_DR1_Q3 DB_ID = 2249 C = 257; O = 6; E = 1.06; R = 5.66; rawP = 0.0007; adjP = 0.0036 hsa_V$HNF4_Q6 DB_ID = 2331 C = 257; O = 6; E = 1.06; R = 5.66; rawP = 0.0007; adjP = 0.0036 hsa_V$NFKB_Q6 DB_ID = 1984 C = 254; O = 6; E = 1.05; R = 5.72; rawP = 0.0007; adjP = 0.0036 hsa_V$STAT_Q6 DB_ID = 2262 C = 258; O = 6; E = 1.06; R = 5.63; rawP = 0.0007; adjP = 0.0036 hsa_V$ICSBP_Q6 DB_ID = 2210 C = 246; O = 6; E = 1.02; R = 5.91; rawP = 0.0006; adjP = 0.0036 hsa_V$CP2_01 DB_ID = 1889 C = 258; O = 6; E = 1.06; R = 5.63; rawP = 0.0007; adjP = 0.0036 hsa_V$TATA_01 DB_ID = 2025 C = 255; O = 6; E = 1.05; R = 5.70; rawP = 0.0007; adjP = 0.0036 hsa_V$STAT_01 DB_ID = 2003 C = 248; O = 6; E = 1.02; R = 5.86; rawP = 0.0006; adjP = 0.0036 hsa_V$TAL1ALPHAE47_01 DB_ID = 1883 C = 249; O = 6; E = 1.03; R = 5.84; rawP = 0.0006; adjP = 0.0036 hsa_V$TST1_01 DB_ID = 1937 C = 256; O = 6; E = 1.06; R = 5.68; rawP = 0.0007; adjP = 0.0036 hsa_V$CREL_01 DB_ID = 1872 C = 255; O = 6; E = 1.05; R = 5.70; rawP = 0.0007; adjP = 0.0036 hsa_V$GATA4_Q3 DB_ID = 2178 C = 246; O = 6; E = 1.02; R = 5.91; rawP = 0.0006; adjP = 0.0036 hsa_V$PAX2_02 DB_ID = 2139 C = 255; O = 6; E = 1.05; R = 5.70; rawP = 0.0007; adjP = 0.0036 hsa_V$MAX_01 DB_ID = 1924 C = 258; O = 6; E = 1.06; R = 5.63; rawP = 0.0007; adjP = 0.0036 hsa_V$PXR_Q2 DB_ID = 2328 C = 254; O = 6; E = 1.05; R = 5.72; rawP = 0.0007; adjP = 0.0036 hsa_V$MYCMAX_01 DB_ID = 1923 C = 252; O = 6; E = 1.04; R = 5.77; rawP = 0.0007; adjP = 0.0036 hsa_V$HSF2_01 DB_ID = 1951 C = 248; O = 6; E = 1.02; R = 5.86; rawP = 0.0006; adjP = 0.0036 hsa_V$AREB6_02 DB_ID = 2079 C = 253; O = 6; E = 1.04; R = 5.75; rawP = 0.0007; adjP = 0.0036 hsa_V$NFAT_Q4_01 DB_ID = 2310 C = 264; O = 6; E = 1.09; R = 5.51; rawP = 0.0008; adjP = 0.0040 hsa_V$CREB_Q2 DB_ID = 1968 C = 262; O = 6; E = 1.08; R = 5.55; rawP = 0.0008; adjP = 0.0040 hsa_V$NMYC_01 DB_ID = 1875 C = 269; O = 6; E = 1.11; R = 5.40; rawP = 0.0009; adjP = 0.0044 hsa_WGGAATGY_V$TEF1_Q6 DB_ID = 2458 C = 370; O = 7; E = 1.53; R = 4.58; rawP = 0.0009; adjP = 0.0044 hsa_V$HAND1E47_01 DB_ID = 2002 C = 274; O = 6; E = 1.13; R = 5.31; rawP = 0.0010; adjP = 0.0048 hsa_V$ATF_B DB_ID = 2056 C = 186; O = 5; E = 0.77; R = 6.51; rawP = 0.0011; adjP = 0.0051 hsa_RGAGGAARY_V$PU1_Q6 DB_ID = 2447 C = 495; O = 8; E = 2.04; R = 3.92; rawP = 0.0011; adjP = 0.0051 hsa_V$TATA_C DB_ID = 1998 C = 279; O = 6; E = 1.15; R = 5.21; rawP = 0.0011; adjP = 0.0051 hsa_GTCNYYATGR_UNKNOWN DB_ID = 2335 C = 108; O = 4; E = 0.45; R = 8.97; rawP = 0.0011; adjP = 0.0051 hsa_V$MAZ_Q6 DB_ID = 2189 C = 189; O = 5; E = 0.78; R = 6.41; rawP = 0.0012; adjP = 0.0054 hsa_V$FXR_IR1_Q6 DB_ID = 2252 C = 110; O = 4; E = 0.45; R = 8.81; rawP = 0.0012; adjP = 0.0054 hsa_V$ETF_Q6 DB_ID = 2208 C = 113; O = 4; E = 0.47; R = 8.58; rawP = 0.0013; adjP = 0.0058 hsa_CTGCAGY_UNKNOWN DB_ID = 2137 C = 756; O = 10; E = 3.12; R = 3.20; rawP = 0.0013; adjP = 0.0058 hsa_GGAMTNNNNNTCCY_UNKNOWN DB_ID = 2269 C = 117; O = 4; E = 0.48; R = 8.28; rawP = 0.0014; adjP = 0.0061 hsa_V$RREB1_01 DB_ID = 2028 C = 204; O = 5; E = 0.84; R = 5.94; rawP = 0.0016; adjP = 0.0067 hsa_RACTNNRTTTNC_UNKNOWN DB_ID = 2347 C = 121; O = 4; E = 0.50; R = 8.01; rawP = 0.0016; adjP = 0.0067 hsa_CAGGTA_V$AREB6_01 DB_ID = 2404 C = 780; O = 10; E = 3.22; R = 3.11; rawP = 0.0016; adjP = 0.0067 hsa_CTTTGA_V$LEF1_Q2 DB_ID = 2427 C = 1208; O = 13; E = 4.99; R = 2.61; rawP = 0.0016; adjP = 0.0067 hsa_V$IRF2_01 DB_ID = 1881 C = 125; O = 4; E = 0.52; R = 7.75; rawP = 0.0018; adjP = 0.0075 hsa_GCCATNTTG_V$YY1_Q6 DB_ID = 2459 C = 419; O = 7; E = 1.73; R = 4.05; rawP = 0.0019; adjP = 0.0078 hsa_V$EVI1_02 DB_ID = 1894 C = 129; O = 4; E = 0.53; R = 7.51; rawP = 0.0021; adjP = 0.0086 hsa_V$LBP1_Q6 DB_ID = 2185 C = 220; O = 5; E = 0.91; R = 5.51; rawP = 0.0023; adjP = 0.0093 hsa_RGAANNTTC_V$HSF1_01 DB_ID = 2425 C = 441; O = 7; E = 1.82; R = 3.85; rawP = 0.0025; adjP = 0.0100 hsa_GATTGGY_V$NFY_Q6_01 DB_ID = 2440 C = 1141; O = 12; E = 4.71; R = 2.55; rawP = 0.0029; adjP = 0.0115 hsa_V$NKX61_01 DB_ID = 2090 C = 236; O = 5; E = 0.97; R = 5.13; rawP = 0.0031; adjP = 0.0122 hsa_V$STAT5B_01 DB_ID = 2113 C = 239; O = 5; E = 0.99; R = 5.07; rawP = 0.0032; adjP = 0.0123 hsa_V$TBP_01 DB_ID = 2125 C = 239; O = 5; E = 0.99; R = 5.07; rawP = 0.0032; adjP = 0.0123 hsa_V$YY1_02 DB_ID = 1886 C = 239; O = 5; E = 0.99; R = 5.07; rawP = 0.0032; adjP = 0.0123 hsa_V$E2F1_Q3 DB_ID = 2095 C = 240; O = 5; E = 0.99; R = 5.05; rawP = 0.0033; adjP = 0.0125 hsa_V$E2A_Q2 DB_ID = 2279 C = 241; O = 5; E = 0.99; R = 5.03; rawP = 0.0034; adjP = 0.0128 hsa_V$CMYB_01 DB_ID = 1849 C = 244; O = 5; E = 1.01; R = 4.96; rawP = 0.0035; adjP = 0.0128 hsa_V$FOXO3_01 DB_ID = 2131 C = 243; O = 5; E = 1.00; R = 4.99; rawP = 0.0035; adjP = 0.0128 hsa_V$GATA1_03 DB_ID = 1931 C = 243; O = 5; E = 1.00; R = 4.99; rawP = 0.0035; adjP = 0.0128 hsa_V$ATF3_Q6 DB_ID = 2156 C = 245; O = 5; E = 1.01; R = 4.94; rawP = 0.0036; adjP = 0.0131 hsa_AAAYWAACM_V$HFH4_01 DB_ID = 2421 C = 250; O = 5; E = 1.03; R = 4.85; rawP = 0.0039; adjP = 0.0137 hsa_V$OCT1_05 DB_ID = 1960 C = 250; O = 5; E = 1.03; R = 4.85; rawP = 0.0039; adjP = 0.0137 hsa_V$PAX4_03 DB_ID = 2066 C = 249; O = 5; E = 1.03; R = 4.87; rawP = 0.0039; adjP = 0.0137 hsa_V$AR_01 DB_ID = 2133 C = 153; O = 4; E = 0.63; R = 6.33; rawP = 0.0038; adjP = 0.0137 hsa_V$CP2_02 DB_ID = 2316 C = 253; O = 5; E = 1.04; R = 4.79; rawP = 0.0041; adjP = 0.0139 hsa_V$MYB_Q6 DB_ID = 1971 C = 253; O = 5; E = 1.04; R = 4.79; rawP = 0.0041; adjP = 0.0139 hsa_V$HLF_01 DB_ID = 2030 C = 253; O = 5; E = 1.04; R = 4.79; rawP = 0.0041; adjP = 0.0139 hsa_V$P53_DECAMER_Q2 DB_ID = 2245 C = 253; O = 5; E = 1.04; R = 4.79; rawP = 0.0041; adjP = 0.0139 hsa_V$ATF_01 DB_ID = 1856 C = 256; O = 5; E = 1.06; R = 4.73; rawP = 0.0043; adjP = 0.0142 hsa_V$IRF1_Q6 DB_ID = 2241 C = 254; O = 5; E = 1.05; R = 4.77; rawP = 0.0042; adjP = 0.0142 hsa_V$SREBP_Q3 DB_ID = 2261 C = 256; O = 5; E = 1.06; R = 4.73; rawP = 0.0043; adjP = 0.0142 hsa_V$AP4_01 DB_ID = 1850 C = 256; O = 5; E = 1.06; R = 4.73; rawP = 0.0043; adjP = 0.0142 hsa_V$ZIC1_01 DB_ID = 2106 C = 257; O = 5; E = 1.06; R = 4.71; rawP = 0.0044; adjP = 0.0144 hsa_RTAAACA_V$FREAC2_01 DB_ID = 2417 C = 907; O = 10; E = 3.74; R = 2.67; rawP = 0.0046; adjP = 0.0145 hsa_V$E12_Q6 DB_ID = 2206 C = 260; O = 5; E = 1.07; R = 4.66; rawP = 0.0046; adjP = 0.0145 hsa_YATTNATC_UNKNOWN DB_ID = 2385 C = 370; O = 6; E = 1.53; R = 3.93; rawP = 0.0045; adjP = 0.0145 hsa_TAANNYSGCG_UNKNOWN DB_ID = 2361 C = 80; O = 3; E = 0.33; R = 9.09; rawP = 0.0045; adjP = 0.0145 hsa_V$NF1_Q6 DB_ID = 1982 C = 259; O = 5; E = 1.07; R = 4.68; rawP = 0.0046; adjP = 0.0145 hsa_V$OSF2_Q6 DB_ID = 2228 C = 261; O = 5; E = 1.08; R = 4.64; rawP = 0.0047; adjP = 0.0146 hsa_WCTCNATGGY_UNKNOWN DB_ID = 2377 C = 81; O = 3; E = 0.33; R = 8.97; rawP = 0.0047; adjP = 0.0146 hsa_V$MYCMAX_02 DB_ID = 1927 C = 263; O = 5; E = 1.09; R = 4.61; rawP = 0.0049; adjP = 0.0148 hsa_V$HNF4_01 DB_ID = 1938 C = 264; O = 5; E = 1.09; R = 4.59; rawP = 0.0049; adjP = 0.0148 hsa_V$HEB_Q6 DB_ID = 2209 C = 263; O = 5; E = 1.09; R = 4.61; rawP = 0.0049; adjP = 0.0148 hsa_V$TCF1P_Q6 DB_ID = 2198 C = 263; O = 5; E = 1.09; R = 4.61; rawP = 0.0049; adjP = 0.0148 hsa_V$ARP1_01 DB_ID = 1954 C = 165; O = 4; E = 0.68; R = 5.87; rawP = 0.0050; adjP = 0.0149 hsa_V$HSF1_01 DB_ID = 1949 C = 265; O = 5; E = 1.09; R = 4.57; rawP = 0.0050; adjP = 0.0149 hsa_SGCGSSAAA_V$E2F1DP2_01 DB_ID = 2410 C = 167; O = 4; E = 0.69; R = 5.80; rawP = 0.0052; adjP = 0.0152 hsa_V$NF1_Q6_01 DB_ID = 2282 C = 267; O = 5; E = 1.10; R = 4.54; rawP = 0.0052; adjP = 0.0152 hsa_V$VDR_Q6 DB_ID = 2325 C = 268; O = 5; E = 1.11; R = 4.52; rawP = 0.0053; adjP = 0.0154 hsa_V$IK1_01 DB_ID = 1902 C = 274; O = 5; E = 1.13; R = 4.42; rawP = 0.0058; adjP = 0.0168 hsa_TGACATY_UNKNOWN DB_ID = 2365 C = 652; O = 8; E = 2.69; R = 2.97; rawP = 0.0059; adjP = 0.0169 hsa_V$AP2REP_01 DB_ID = 2122 C = 176; O = 4; E = 0.73; R = 5.51; rawP = 0.0063; adjP = 0.0180 hsa_TGANTCA_V$AP1_C DB_ID = 2402 C = 1104; O = 11; E = 4.56; R = 2.41; rawP = 0.0064; adjP = 0.0181 hsa_YGACNNYACAR_UNKNOWN DB_ID = 2387 C = 94; O = 3; E = 0.39; R = 7.73; rawP = 0.0070; adjP = 0.0197 hsa_STTTCRNTTT_V$IRF_Q6 DB_ID = 2426 C = 186; O = 4; E = 0.77; R = 5.21; rawP = 0.0076; adjP = 0.0213 hsa_V$HFH3_01 DB_ID = 2043 C = 189; O = 4; E = 0.78; R = 5.13; rawP = 0.0080; adjP = 0.0222 hsa_ACTWSNACTNY_UNKNOWN DB_ID = 1939 C = 102; O = 3; E = 0.42; R = 7.13; rawP = 0.0088; adjP = 0.0243 hsa_V$FOXD3_01 DB_ID = 1934 C = 196; O = 4; E = 0.81; R = 4.94; rawP = 0.0091; adjP = 0.0250 hsa_TTCYRGAA_UNKNOWN DB_ID = 2374 C = 325; O = 5; E = 1.34; R = 3.73; rawP = 0.0115; adjP = 0.0313 hsa_CCANNAGRKGGC_UNKNOWN DB_ID = 2038 C = 113; O = 3; E = 0.47; R = 6.43; rawP = 0.0116; adjP = 0.0314 hsa_TTCYNRGAA_V$STAT5B_01 DB_ID = 2455 C = 328; O = 5; E = 1.35; R = 3.69; rawP = 0.0119; adjP = 0.0318 hsa_V$AR_02 DB_ID = 2317 C = 40; O = 2; E = 0.17; R = 12.11; rawP = 0.0119; adjP = 0.0318 hsa_V$HNF3B_01 DB_ID = 1935 C = 217; O = 4; E = 0.90; R = 4.47; rawP = 0.0128; adjP = 0.0340 hsa_V$CREB_Q2_01 DB_ID = 2293 C = 219; O = 4; E = 0.90; R = 4.43; rawP = 0.0132; adjP = 0.0346 hsa_TCANNTGAY_V$SREBP1_01 DB_ID = 2453 C = 466; O = 6; E = 1.92; R = 3.12; rawP = 0.0132; adjP = 0.0346 hsa_WTGAAAT_UNKNOWN DB_ID = 2379 C = 609; O = 7; E = 2.51; R = 2.78; rawP = 0.0137; adjP = 0.0357 hsa_V$E2F1_Q6 DB_ID = 2097 C = 228; O = 4; E = 0.94; R = 4.25; rawP = 0.0151; adjP = 0.0383 hsa_V$E2F1DP1_01 DB_ID = 2231 C = 231; O = 4; E = 0.95; R = 4.20; rawP = 0.0157; adjP = 0.0383 hsa_V$E2F1DP1RB_01 DB_ID = 2235 C = 228; O = 4; E = 0.94; R = 4.25; rawP = 0.0151; adjP = 0.0383 hsa_V$GRE_C DB_ID = 1990 C = 124; O = 3; E = 0.51; R = 5.86; rawP = 0.0149; adjP = 0.0383 hsa_V$MZF1_01 DB_ID = 1899 C = 231; O = 4; E = 0.95; R = 4.20; rawP = 0.0157; adjP = 0.0383 hsa_V$E2F_Q4 DB_ID = 2092 C = 231; O = 4; E = 0.95; R = 4.20; rawP = 0.0157; adjP = 0.0383 hsa_V$E2F_Q6 DB_ID = 2094 C = 229; O = 4; E = 0.95; R = 4.23; rawP = 0.0153; adjP = 0.0383 hsa_V$E2F4DP2_01 DB_ID = 2234 C = 231; O = 4; E = 0.95; R = 4.20; rawP = 0.0157; adjP = 0.0383 hsa_V$E2F_02 DB_ID = 1870 C = 231; O = 4; E = 0.95; R = 4.20; rawP = 0.0157; adjP = 0.0383 hsa_V$E2F1DP2_01 DB_ID = 2232 C = 231; O = 4; E = 0.95; R = 4.20; rawP = 0.0157; adjP = 0.0383 hsa_V$ATF1_Q6 DB_ID = 2205 C = 230; O = 4; E = 0.95; R = 4.21; rawP = 0.0155; adjP = 0.0383 hsa_V$NKX3A_01 DB_ID = 2109 C = 232; O = 4; E = 0.96; R = 4.18; rawP = 0.0160; adjP = 0.0389 hsa_V$PAX4_02 DB_ID = 2065 C = 233; O = 4; E = 0.96; R = 4.16; rawP = 0.0162; adjP = 0.0391 hsa_V$CDPCR1_01 DB_ID = 1912 C = 130; O = 3; E = 0.54; R = 5.59; rawP = 0.0169; adjP = 0.0399 hsa_CTAWWWATA_V$RSRFC4_Q2 DB_ID = 2448 C = 358; O = 5; E = 1.48; R = 3.38; rawP = 0.0168; adjP = 0.0399 hsa_V$E2F4DP1_01 DB_ID = 2233 C = 236; O = 4; E = 0.97; R = 4.11; rawP = 0.0169; adjP = 0.0399 hsa_V$SOX9_B1 DB_ID = 2076 C = 236; O = 4; E = 0.97; R = 4.11; rawP = 0.0169; adjP = 0.0399 hsa_V$MEIS1_01 DB_ID = 2085 C = 237; O = 4; E = 0.98; R = 4.09; rawP = 0.0171; adjP = 0.0400 hsa_V$FOXO1_02 DB_ID = 2129 C = 238; O = 4; E = 0.98; R = 4.07; rawP = 0.0173; adjP = 0.0400 hsa_V$GATA3_01 DB_ID = 1892 C = 238; O = 4; E = 0.98; R = 4.07; rawP = 0.0173; adjP = 0.0400 hsa_V$CACBINDINGPROTEIN_Q6 DB_ID = 2219 C = 238; O = 4; E = 0.98; R = 4.07; rawP = 0.0173; adjP = 0.0400 hsa_V$NKX62_Q2 DB_ID = 2140 C = 239; O = 4; E = 0.99; R = 4.06; rawP = 0.0176; adjP = 0.0404 hsa_V$SP1_Q6_01 DB_ID = 2307 C = 240; O = 4; E = 0.99; R = 4.04; rawP = 0.0178; adjP = 0.0405 hsa_V$HNF1_C DB_ID = 1991 C = 240; O = 4; E = 0.99; R = 4.04; rawP = 0.0178; adjP = 0.0405 hsa_V$NFY_C DB_ID = 1993 C = 241; O = 4; E = 0.99; R = 4.02; rawP = 0.0181; adjP = 0.0409 hsa_GGGNNTTTCC_V$NFKB_Q6_01 DB_ID = 2439 C = 134; O = 3; E = 0.55; R = 5.42; rawP = 0.0183; adjP = 0.0412 hsa_V$MYOD_Q6 DB_ID = 1973 C = 244; O = 4; E = 1.01; R = 3.97; rawP = 0.0188; adjP = 0.0418 hsa_V$STAT1_03 DB_ID = 2147 C = 244; O = 4; E = 1.01; R = 3.97; rawP = 0.0188; adjP = 0.0418 hsa_V$NERF_Q2 DB_ID = 2163 C = 245; O = 4; E = 1.01; R = 3.96; rawP = 0.0191; adjP = 0.0421 hsa_V$SREBP1_Q6 DB_ID = 2242 C = 245; O = 4; E = 1.01; R = 3.96; rawP = 0.0191; adjP = 0.0421 hsa_V$IRF1_01 DB_ID = 1880 C = 247; O = 4; E = 1.02; R = 3.92; rawP = 0.0196; adjP = 0.0427 hsa_V$ETS_Q4 DB_ID = 2255 C = 247; O = 4; E = 1.02; R = 3.92; rawP = 0.0196; adjP = 0.0427 hsa_WCAANNNYCAG_UNKNOWN DB_ID = 2376 C = 248; O = 4; E = 1.02; R = 3.91; rawP = 0.0198; adjP = 0.0429 hsa_V$AP2_Q3 DB_ID = 2275 C = 249; O = 4; E = 1.03; R = 3.89; rawP = 0.0201; adjP = 0.0431 hsa_V$STAT1_02 DB_ID = 2143 C = 249; O = 4; E = 1.03; R = 3.89; rawP = 0.0201; adjP = 0.0431 hsa_V$PBX1_01 DB_ID = 1907 C = 250; O = 4; E = 1.03; R = 3.88; rawP = 0.0204; adjP = 0.0436 hsa_TGACAGNY_V$MEIS1_01 DB_ID = 2432 C = 819; O = 8; E = 3.38; R = 2.37; rawP = 0.0210; adjP = 0.0444 hsa_V$AP4_Q6_01 DB_ID = 2304 C = 252; O = 4; E = 1.04; R = 3.85; rawP = 0.0209; adjP = 0.0444 hsa_V$USF_Q6 DB_ID = 1976 C = 255; O = 4; E = 1.05; R = 3.80; rawP = 0.0217; adjP = 0.0454 hsa_V$ETS1_B DB_ID = 2057 C = 255; O = 4; E = 1.05; R = 3.80; rawP = 0.0217; adjP = 0.0454 hsa_V$AP2_Q6 DB_ID = 1978 C = 256; O = 4; E = 1.06; R = 3.79; rawP = 0.0220; adjP = 0.0456 hsa_V$ZID_01 DB_ID = 1901 C = 256; O = 4; E = 1.06; R = 3.79; rawP = 0.0220; adjP = 0.0456 hsa_V$NFY_Q6 DB_ID = 1974 C = 258; O = 4; E = 1.06; R = 3.76; rawP = 0.0225; adjP = 0.0464 hsa_V$GFI1_01 DB_ID = 2023 C = 260; O = 4; E = 1.07; R = 3.73; rawP = 0.0231; adjP = 0.0467 hsa_V$PAX4_01 DB_ID = 2064 C = 261; O = 4; E = 1.08; R = 3.71; rawP = 0.0234; adjP = 0.0467 hsa_V$PR_01 DB_ID = 2318 C = 147; O = 3; E = 0.61; R = 4.94; rawP = 0.0233; adjP = 0.0467 hsa_V$NFY_Q6_01 DB_ID = 2260 C = 261; O = 4; E = 1.08; R = 3.71; rawP = 0.0234; adjP = 0.0467 hsa_V$STAT4_01 DB_ID = 2150 C = 261; O = 4; E = 1.08; R = 3.71; rawP = 0.0234; adjP = 0.0467 hsa_V$LMO2COM_01 DB_ID = 2034 C = 260; O = 4; E = 1.07; R = 3.73; rawP = 0.0231; adjP = 0.0467 hsa_V$NKX25_02 DB_ID = 2014 C = 260; O = 4; E = 1.07; R = 3.73; rawP = 0.0231; adjP = 0.0467 hsa_V$GATA_C DB_ID = 1989 C = 263; O = 4; E = 1.09; R = 3.68; rawP = 0.0240; adjP = 0.0476 hsa_YTAAYNGCT_UNKNOWN DB_ID = 2396 C = 149; O = 3; E = 0.61; R = 4.88; rawP = 0.0241; adjP = 0.0476 hsa_V$ER_Q6_01 DB_ID = 2290 C = 264; O = 4; E = 1.09; R = 3.67; rawP = 0.0243; adjP = 0.0478 hsa_SCGGAAGY_V$ELK1_02 DB_ID = 2413 C = 1176; O = 10; E = 4.85; R = 2.06; rawP = 0.0247; adjP = 0.0479 hsa_V$CEBP_01 DB_ID = 1958 C = 266; O = 4; E = 1.10; R = 3.64; rawP = 0.0249; adjP = 0.0479 hsa_V$AP2_Q6_01 DB_ID = 2292 C = 265; O = 4; E = 1.09; R = 3.66; rawP = 0.0246; adjP = 0.0479 hsa_V$EGR1_01 DB_ID = 2017 C = 266; O = 4; E = 1.10; R = 3.64; rawP = 0.0249; adjP = 0.0479 hsa_V$CEBP_Q2_01 DB_ID = 2288 C = 265; O = 4; E = 1.09; R = 3.66; rawP = 0.0246; adjP = 0.0479 hsa_V$CREB_Q4 DB_ID = 1969 C = 267; O = 4; E = 1.10; R = 3.63; rawP = 0.0252; adjP = 0.0480 hsa_V$AREB6_01 DB_ID = 2078 C = 267; O = 4; E = 1.10; R = 3.63; rawP = 0.0252; adjP = 0.0480 hsa_V$EFC_Q6 DB_ID = 2175 C = 268; O = 4; E = 1.11; R = 3.62; rawP = 0.0255; adjP = 0.0484 hsa_V$AP4_Q5 DB_ID = 1966 C = 270; O = 4; E = 1.11; R = 3.59; rawP = 0.0261; adjP = 0.0493

TABLE 6a PPI and biological pathways (wikipathways and pathways commons) gene set enrichment analysis. PPI set from Webgestalt Set ID Enrichment Statistics Hsapiens_Module_866 DB_ID = 866 C = 19; O = 5; E = 0.19; R = 25.94; rawP = 1.05e−06; adjP = 6.93e−05 Hsapiens_Module_596 DB_ID = 596 C = 36; O = 5; E = 0.37; R = 13.69; rawP = 2.96e−05; adjP = 0.0007 Hsapiens_Module_17 DB_ID = 17 C = 6; O = 3; E = 0.06; R = 49.28; rawP = 2.01e−05; adjP = 0.0007 Hsapiens_Module_287 DB_ID = 287 C = 115; O = 7; E = 1.17; R = 6.00; rawP = 0.0002; adjP = 0.0026 Hsapiens_Module_25 DB_ID = 25 C = 1871; O = 35; E = 18.98; R = 1.84; rawP = 0.0002; adjP = 0.0026 Hsapiens_Module_669 DB_ID = 669 C = 6; O = 2; E = 0.06; R = 32.85; rawP = 0.0015; adjP = 0.0165 Hsapiens_Module_845 DB_ID = 845 C = 24; O = 3; E = 0.24; R = 12.32; rawP = 0.0018; adjP = 0.0170 Hsapiens_Module_94 DB_ID = 94 C = 9; O = 2; E = 0.09; R = 21.90; rawP = 0.0035; adjP = 0.0289 Hsapiens_Module_110 DB_ID = 110 C = 212; O = 7; E = 2.15; R = 3.25; rawP = 0.0059; adjP = 0.0433 Hsapiens_Module_203 DB_ID = 203 C = 341; O = 9; E = 3.46; R = 2.60; rawP = 0.0081; adjP = 0.0486 Hsapiens_Module_951 DB_ID = 951 C = 13; O = 2; E = 0.13; R = 15.16; rawP = 0.0074; adjP = 0.0486

TABLE 6b Wikipathways modules enriched for pAID associated candidate genes PPI set Set ID Enrichment Statistics Inflammatory Response Pathway WP = 453 C = 32; O = 6; E = 0.13; R = 45.43; rawP = 3.77e−09; adjP = 2.15e−07 Cytokines and Inflammatory Response WP = 530 C = 67; O = 6; E = 0.28; R = 21.70; rawP = 3.68e−07; adjP = 1.05e−05 Th1-Th2 WP = 1722 C = 7; O = 3; E = 0.03; R = 103.84; rawP = 2.39e−06; adjP = 4.54e−05 AGE-RAGE pathway WP = 2324 C = 76; O = 5; E = 0.31; R = 15.94; rawP = 1.65e−05; adjP = 0.0002 IL-12 SIGNALING PATHWAY WP = 2111 C = 11; O = 3; E = 0.05; R = 66.08; rawP = 1.11e−05; adjP = 0.0002 IL-4 signaling pathway WP = 395 C = 59; O = 4; E = 0.24; R = 16.43; rawP = 0.0001; adjP = 0.0008 Senescence and Autophagy WP = 615 C = 120; O = 5; E = 0.50; R = 10.10; rawP = 0.0001; adjP = 0.0008 Arylamine metabolism WP = 694 C = 9; O = 2; E = 0.04; R = 53.84; rawP = 0.0006; adjP = 0.0043 Allograft rejection WP = 2328 C = 119; O = 4; E = 0.49; R = 8.14; rawP = 0.0015; adjP = 0.0095 IL-6 signaling pathway WP = 364 C = 58; O = 3; E = 0.24; R = 12.53; rawP = 0.0018; adjP = 0.0103 Sulfation Biotransformation Reaction WP = 692 C = 17; O = 2; E = 0.07; R = 28.50; rawP = 0.0022; adjP = 0.0114 Kit receptor signaling pathway WP = 304 C = 66; O = 3; E = 0.27; R = 11.01; rawP = 0.0026; adjP = 0.0123 Epithelium TarBase WP = 2002 C = 340; O = 6; E = 1.40; R = 4.28; rawP = 0.0030; adjP = 0.0132 Leptin signaling pathway WP = 2034 C = 81; O = 3; E = 0.33; R = 8.97; rawP = 0.0047; adjP = 0.0191 Folate Metabolism WP = 176 C = 29; O = 2; E = 0.12; R = 16.71; rawP = 0.0064; adjP = 0.0197 Apoptosis WP = 254 C = 92; O = 3; E = 0.38; R = 7.90; rawP = 0.0066; adjP = 0.0197 Androgen receptor signaling pathway WP = 138 C = 91; O = 3; E = 0.38; R = 7.99; rawP = 0.0064; adjP = 0.0197 Integrated Pancreatic Cancer Pathway WP = 2256 C = 181; O = 4; E = 0.75; R = 5.35; rawP = 0.0069; adjP = 0.0197 DNA damage response (only ATM WP = 710 C = 89; O = 3; E = 0.37; R = 8.17; rawP = 0.0061; adjP = 0.0197 dependent) Oncostatin M Signaling Pathway WP = 2358 C = 85; O = 3; E = 0.35; R = 8.55; rawP = 0.0053; adjP = 0.0197 NOD pathway WP = 1433 C = 39; O = 2; E = 0.16; R = 12.42; rawP = 0.0114; adjP = 0.0309 TSLP Signaling Pathway WP = 2203 C = 49; O = 2; E = 0.20; R = 9.89; rawP = 0.0175; adjP = 0.0399 IL-5 signaling pathway WP = 127 C = 47; O = 2; E = 0.19; R = 10.31; rawP = 0.0162; adjP = 0.0399 Interleukin-11 Signaling Pathway WP = 2332 C = 49; O = 2; E = 0.20; R = 9.89; rawP = 0.0175; adjP = 0.0399 Adipogenesis WP = 236 C = 130; O = 3; E = 0.54; R = 5.59; rawP = 0.0169; adjP = 0.0399 Alpha 6 Beta 4 signaling pathway WP = 244 C = 50; O = 2; E = 0.21; R = 9.69; rawP = 0.0182; adjP = 0.0399 IL-2 Signaling pathway WP = 49 C = 53; O = 2; E = 0.22; R = 9.14; rawP = 0.0203; adjP = 0.0429 IL-3 Signaling Pathway WP = 286 C = 54; O = 2; E = 0.22; R = 8.97; rawP = 0.0211; adjP = 0.0430

TABLE 6c Pathways commons modules enriched for pAID associated candidate genes Pathway Set ID Enrichment Statistics EGF receptor (ErbB1) signaling DB_ID = 1550 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; pathway adjP = 6.92e−19 ErbB receptor signaling network DB_ID = 1573 C = 1312; O = 37; E = 5.42; R = 6.83; rawP = 1.78e−20; adjP = 6.92e−19 Beta1 integrin cell surface DB_ID = 1517 C = 1351; O = 37; E = 5.58; R = 6.64; rawP = 4.69e−20; interactions adjP = 6.92e−19 Urokinase-type plasminogen DB_ID = 1519 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; activator (uPA) and uPAR- adjP = 6.92e−19 mediated signaling PDGFR-beta signaling pathway DB_ID = 1540 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adjP = 6.92e−19 Insulin Pathway DB_ID = 1466 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adjP = 6.92e−19 EGFR-dependant Endothelin DB_ID = 1603 C = 1289; O = 36; E = 5.32; R = 6.77; rawP = 8.59e−20; signaling events adjP = 6.92e−19 Arf6 trafficking events DB_ID = 1615 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adjP = 6.92e−19 IFN-gamma pathway DB_ID = 1529 C = 1296; O = 36; E = 5.35; R = 6.73; rawP = 1.02e−19; adjP = 6.92e−19 PAR1-mediated thrombin signaling DB_ID = 1531 C = 1299; O = 36; E = 5.36; R = 6.71; rawP = 1.10e−19; events adjP = 6.92e−19 Thrombin/protease-activated DB_ID = 1552 C = 1300; O = 36; E = 5.37; R = 6.71; rawP = 1.13e−19; receptor (PAR) pathway adjP = 6.92e−19 GMCSF-mediated signaling events DB_ID = 1461 C = 1292; O = 36; E = 5.33; R = 6.75; rawP = 9.26e−20; adjP = 6.92e−19 Signaling events mediated by DB_ID = 1491 C = 1293; O = 36; E = 5.34; R = 6.75; rawP = 9.49e−20; Hepatocyte Growth Factor adjP = 6.92e−19 Receptor (c-Met) Internalization of ErbB1 DB_ID = 1509 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adjP = 6.92e−19 IGF1 pathway DB_ID = 1482 C = 1291; O = 36; E = 5.33; R = 6.76; rawP = 9.03e−20; adjP = 6.92e−19 Signaling events mediated by focal DB_ID = 1574 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adhesion kinase adjP = 6.92e−19 Integrin family cell surface DB_ID = 1499 C = 1378; O = 38; E = 5.69; R = 6.68; rawP = 1.07e−20; interactions adjP = 6.92e−19 Syndecan-1-mediated signaling DB_ID = 1454 C = 1300; O = 36; E = 5.37; R = 6.71; rawP = 1.13e−19; events adjP = 6.92e−19 Arf6 signaling events DB_ID = 1554 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adjP = 6.92e−19 Nectin adhesion pathway DB_ID = 1472 C = 1295; O = 36; E = 5.34; R = 6.74; rawP = 9.98e−20; adjP = 6.92e−19 Class I PI3K signaling events DB_ID = 1553 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adjP = 6.92e−19 mTOR signaling pathway DB_ID = 1571 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adjP = 6.92e−19 Class I PI3K signaling events DB_ID = 1648 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; mediated by Akt adjP = 6.92e−19 TRAIL signaling pathway DB_ID = 1480 C = 1328; O = 37; E = 5.48; R = 6.75; rawP = 2.66e−20; adjP = 6.92e−19 Plasma membrane estrogen DB_ID = 1556 C = 1301; O = 36; E = 5.37; R = 6.70; rawP = 1.16e−19; receptor signaling adjP = 6.92e−19 IL3-mediated signaling events DB_ID = 1564 C = 1295; O = 36; E = 5.34; R = 6.74; rawP = 9.98e−20; adjP = 6.92e−19 Signaling events mediated by DB_ID = 1516 C = 1296; O = 36; E = 5.35; R = 6.73; rawP = 1.02e−19; VEGFR1 and VEGFR2 adjP = 6.92e−19 PDGF receptor signaling network DB_ID = 1497 C = 1293; O = 36; E = 5.34; R = 6.75; rawP = 9.49e−20; adjP = 6.92e−19 S1P1 pathway DB_ID = 1594 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adjP = 6.92e−19 Arf6 downstream pathway DB_ID = 1585 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adjP = 6.92e−19 Glypican 1 network DB_ID = 1492 C = 1299; O = 36; E = 5.36; R = 6.71; rawP = 1.10e−19; adjP = 6.92e−19 IL5-mediated signaling events DB_ID = 1627 C = 1292; O = 36; E = 5.33; R = 6.75; rawP = 9.26e−20; adjP = 6.92e−19 ErbB1 downstream signaling DB_ID = 1602 C = 1288; O = 36; E = 5.32; R = 6.77; rawP = 8.38e−20; adjP = 6.92e−19 Alpha9 beta1 integrin signaling DB_ID = 1578 C = 1305; O = 36; E = 5.39; R = 6.68; rawP = 1.28e−19; events adjP = 7.20e−19 VEGF and VEGFR signaling network DB_ID = 1575 C = 1304; O = 36; E = 5.38; R = 6.69; rawP = 1.25e−19; adjP = 7.20e−19 Endothelins DB_ID = 1619 C = 1307; O = 36; E = 5.39; R = 6.67; rawP = 1.34e−19; adjP = 7.33e−19 LKB1 signaling events DB_ID = 1649 C = 1308; O = 36; E = 5.40; R = 6.67; rawP = 1.38e−19; adjP = 7.35e−19 Sphingosine 1-phosphate (S1P) DB_ID = 1635 C = 1311; O = 36; E = 5.41; R = 6.65; rawP = 1.48e−19; pathway adjP = 7.67e−19 Glypican pathway DB_ID = 1459 C = 1338; O = 36; E = 5.52; R = 6.52; rawP = 2.85e−19; adjP = 1.44e−18 Proteoglycan syndecan-mediated DB_ID = 1637 C = 1345; O = 36; E = 5.55; R = 6.48; rawP = 3.37e−19; signaling events adjP = 1.66e−18 IL12-mediated signaling events DB_ID = 1633 C = 113; O = 14; E = 0.47; R = 30.02; rawP = 4.76e−17; adjP = 2.29e−16 AP-1 transcription factor network DB_ID = 1565 C = 623; O = 24; E = 2.57; R = 9.33; rawP = 1.80e−16; adjP = 8.44e−16 Integrin-linked kinase signaling DB_ID = 1546 C = 656; O = 24; E = 2.71; R = 8.86; rawP = 5.67e−16; adjP = 2.60e−15 CDC42 signaling events DB_ID = 1488 C = 757; O = 24; E = 3.12; R = 7.68; rawP = 1.32e−14; adjP = 5.91e−14 Regulation of CDC42 activity DB_ID = 1456 C = 770; O = 24; E = 3.18; R = 7.55; rawP = 1.90e−14; adjP = 8.32e−14 Calcineurin-regulated NFAT- DB_ID = 1502 C = 49; O = 9; E = 0.20; R = 44.50; rawP = 5.05e−13; adjP = 2.16e−12 dependent transcription in lymphocytes IL23-mediated signaling events DB_ID = 1628 C = 66; O = 9; E = 0.27; R = 33.04; rawP = 8.57e−12; adjP = 3.59e−11 IL1-mediated signaling events DB_ID = 1500 C = 234; O = 13; E = 0.97; R = 13.46; rawP = 2.12e−11; adjP = 8.70e−11 Regulation of nuclear SMAD2/3 DB_ID = 1611 C = 305; O = 14; E = 1.26; R = 11.12; rawP = 4.48e−11; signaling adjP = 1.73e−10 Regulation of cytoplasmic and DB_ID = 1440 C = 305; O = 14; E = 1.26; R = 11.12; rawP = 4.48e−11; nuclear SMAD2/3 signaling adjP = 1.73e−10 TGF-beta receptor signaling DB_ID = 1510 C = 305; O = 14; E = 1.26; R = 11.12; rawP = 4.48e−11; adjP = 1.73e−10 ALK1 signaling events DB_ID = 1612 C = 321; O = 14; E = 1.32; R = 10.57; rawP = 8.78e−11; adjP = 3.33e−10 ALK1 pathway DB_ID = 1583 C = 324; O = 14; E = 1.34; R = 10.47; rawP = 9.93e−11; adjP = 3.69e−10 Regulation of p38-alpha and p38- DB_ID = 1536 C = 164; O = 11; E = 0.68; R = 16.25; rawP = 1.03e−10; beta adjP = 3.76e−10 Role of Calcineurin- DB_ID = 1587 C = 95; O = 9; E = 0.39; R = 22.95; rawP = 2.46e−10; adjP = 8.81e−10 dependent NFAT signaling in lymphocytes TNF receptor signaling pathway DB_ID = 1600 C = 299; O = 13; E = 1.23; R = 10.53; rawP = 4.38e−10; adjP = 1.54e−09 p38 MAPK signaling pathway DB_ID = 1549 C = 189; O = 11; E = 0.78; R = 14.10; rawP = 4.70e−10; adjP = 1.62e−09 Immune System DB_ID = 522 C = 532; O = 16; E = 2.20; R = 7.29; rawP = 8.90e−10; adjP = 3.02e−09 IL27-mediated signaling events DB_ID = 1463 C = 26; O = 6; E = 0.11; R = 55.91; rawP = 9.76e−10; adjP = 3.26e−09 BMP receptor signaling DB_ID = 1644 C = 226; O = 11; E = 0.93; R = 11.79; rawP = 3.10e−09; adjP = 1.00e−08 IL12 signaling mediated by STAT4 DB_ID = 1533 C = 31; O = 6; E = 0.13; R = 46.89; rawP = 3.07e−09; adjP = 1.00e−08 Validated transcriptional DB_ID = 1592 C = 136; O = 9; E = 0.56; R = 16.03; rawP = 6.05e−09; targets of AP1 family members adjP = 1.92e−08 Fra1 and Fra2 CXCR4-mediated signaling events DB_ID = 1593 C = 192; O = 10; E = 0.79; R = 12.62; rawP = 8.61e−09; adjP = 2.69e−08 IL2-mediated signaling events DB_ID = 1558 C = 115; O = 8; E = 0.47; R = 16.85; rawP = 2.92e−08; adjP = 8.99e−08 Glucocorticoid receptor regulatory DB_ID = 1577 C = 80; O = 7; E = 0.33; R = 21.20; rawP = 4.47e−08; adjP = 1.35e−07 network Glucocorticoid receptor signaling DB_ID = 1569 C = 85; O = 7; E = 0.35; R = 19.95; rawP = 6.82e−08; adjP = 2.04e−07 TCR signaling in na&#xef; ve CD4+ DB_ID = 1624 C = 135; O = 8; E = 0.56; R = 14.36; rawP = 1.02e−07; T cells adjP = 3.00e−07 Calcium signaling in the CD4+ TCR DB_ID = 1639 C = 29; O = 5; E = 0.12; R = 41.77; rawP = 1.24e−07; adjP = 3.59e−07 pathway Hemostasis DB_ID = 64 C = 376; O = 11; E = 1.55; R = 7.09; rawP = 5.43e−07; adjP = 1.55e−06 JNK signaling in the CD4+ TCR DB_ID = 1586 C = 42; O = 5; E = 0.17; R = 28.84; rawP = 8.51e−07; adjP = 2.36e−06 pathway Ras signaling in the CD4+ TCR DB_ID = 1520 C = 42; O = 5; E = 0.17; R = 28.84; rawP = 8.51e−07; adjP = 2.36e−06 pathway Cytokine Signaling in Immune DB_ID = 1120 C = 193; O = 8; E = 0.80; R = 10.04; rawP = 1.55e−06; system adjP = 4.24e−06 Signaling events mediated by DB_ID = 1514 C = 92; O = 6; E = 0.38; R = 15.80; rawP = 2.41e−06; adjP = 6.42e−06 TCPTP Signaling by Interleukins DB_ID = 1129 C = 92; O = 6; E = 0.38; R = 15.80; rawP = 2.41e−06; adjP = 6.42e−06 Interleukin-3,5 and GM-CSF DB_ID = 1132 C = 29; O = 4; E = 0.12; R = 33.42; rawP = 6.15e−06; adjP = 1.59e−05 signaling IL4-mediated signaling events DB_ID = 1588 C = 62; O = 5; E = 0.26; R = 19.54; rawP = 6.05e−06; adjP = 1.59e−05 Factors involved in DB_ID = 109 C = 119; O = 5; E = 0.49; R = 10.18; rawP = 0.0001; adjP = 0.0002 megakaryocyte development and platelet production Developmental Biology DB_ID = 11 C = 433; O = 9; E = 1.79; R = 5.04; rawP = 8.63e−05; adjP = 0.0002 p75(NTR)-mediated signaling DB_ID = 1551 C = 178; O = 6; E = 0.73; R = 8.17; rawP = 0.0001; adjP = 0.0002 3-phosphoinositide degradation DB_ID = 1390 C = 19; O = 3; E = 0.08; R = 38.26; rawP = 6.38e−05; adjP = 0.0002 Signaling events mediated by DB_ID = 1591 C = 52; O = 4; E = 0.21; R = 18.64; rawP = 6.51e−05; adjP = 0.0002 PTP1B Interleukin-2 signaling DB_ID = 1128 C = 28; O = 3; E = 0.12; R = 25.96; rawP = 0.0002; adjP = 0.0005 IL2 signaling events mediated by DB_ID = 1442 C = 28; O = 3; E = 0.12; R = 25.96; rawP = 0.0002; adjP = 0.0005 STAT5 Signaling events regulated by Ret DB_ID = 1566 C = 69; O = 4; E = 0.28; R = 14.05; rawP = 0.0002; adjP = 0.0005 tyrosine kinase NOD1/2 Signaling Pathway DB_ID = 1145 C = 26; O = 3; E = 0.11; R = 27.96; rawP = 0.0002; adjP = 0.0005 IL2 signaling events mediated by DB_ID = 1634 C = 67; O = 4; E = 0.28; R = 14.46; rawP = 0.0002; adjP = 0.0005 PI3K a6b1 and a6b4 Integrin signaling DB_ID = 1622 C = 35; O = 3; E = 0.14; R = 20.77; rawP = 0.0004; adjP = 0.0009 amb2 Integrin signaling DB_ID = 1568 C = 41; O = 3; E = 0.17; R = 17.73; rawP = 0.0007; adjP = 0.0016 Nucleotide-binding domain, DB_ID = 1144 C = 43; O = 3; E = 0.18; R = 16.90; rawP = 0.0008; adjP = 0.0018 leucine rich repeat containing receptor (NLR) signaling pathways LPA receptor mediated events DB_ID = 1481 C = 100; O = 4; E = 0.41; R = 9.69; rawP = 0.0008; adjP = 0.0018 E-cadherin signaling in the DB_ID = 1544 C = 275; O = 6; E = 1.14; R = 5.29; rawP = 0.0010; adjP = 0.0021 nascent adherens junction Stabilization and expansion of DB_ID = 1469 C = 275; O = 6; E = 1.14; R = 5.29; rawP = 0.0010; adjP = 0.0021 the E-cadherin adherens junction IL6-mediated signaling events DB_ID = 1445 C = 47; O = 3; E = 0.19; R = 15.47; rawP = 0.0010; adjP = 0.0021 E-cadherin signaling events DB_ID = 1617 C = 280; O = 6; E = 1.16; R = 5.19; rawP = 0.0011; adjP = 0.0023 Regulation of beta-cell DB_ID = 35 C = 109; O = 4; E = 0.45; R = 8.89; rawP = 0.0011; adjP = 0.0023 development FoxO family signaling DB_ID = 1557 C = 49; O = 3; E = 0.20; R = 14.83; rawP = 0.0011; adjP = 0.0023 KitReceptor DB_ID = 1658 C = 54; O = 3; E = 0.22; R = 13.46; rawP = 0.0015; adjP = 0.0030 Endogenous TLR signaling DB_ID = 1645 C = 57; O = 3; E = 0.24; R = 12.75; rawP = 0.0017; adjP = 0.0034 CD40/CD40L signaling DB_ID = 1479 C = 58; O = 3; E = 0.24; R = 12.53; rawP = 0.0018; adjP = 0.0036 TCR signaling in na&#xef; ve CD8+ DB_ID = 1521 C = 129; O = 4; E = 0.53; R = 7.51; rawP = 0.0021; adjP = 0.0041 T cells Regulation of retinoblastoma DB_ID = 1623 C = 66; O = 3; E = 0.27; R = 11.01; rawP = 0.0026; adjP = 0.0051 protein Regulation of Telomerase DB_ID = 1507 C = 68; O = 3; E = 0.28; R = 10.69; rawP = 0.0028; adjP = 0.0054 Adaptive Immune System DB_ID = 515 C = 243; O = 5; E = 1.00; R = 4.99; rawP = 0.0035; adjP = 0.0067 N-cadherin signaling events DB_ID = 1494 C = 251; O = 5; E = 1.04; R = 4.83; rawP = 0.0040; adjP = 0.0075 Signaling events mediated by PRL DB_ID = 1651 C = 23; O = 2; E = 0.09; R = 21.07; rawP = 0.0040; adjP = 0.0075 Integration of energy metabolism DB_ID = 812 C = 83; O = 3; E = 0.34; R = 8.76; rawP = 0.0050; adjP = 0.0093 Transmembrane transport of small DB_ID = 937 C = 379; O = 6; E = 1.56; R = 3.84; rawP = 0.0051; adjP = 0.0094 molecules Ca-dependent events DB_ID = 493 C = 27; O = 2; E = 0.11; R = 17.95; rawP = 0.0056; adjP = 0.0102 Negative regulators of RIG- DB_ID = 1121 C = 28; O = 2; E = 0.12; R = 17.31; rawP = 0.0060; adjP = 0.0108 I/MDA5 signaling S1P3 pathway DB_ID = 1526 C = 29; O = 2; E = 0.12; R = 16.71; rawP = 0.0064; adjP = 0.0114 Insulin-mediated glucose transport DB_ID = 1576 C = 29; O = 2; E = 0.12; R = 16.71; rawP = 0.0064; adjP = 0.0114 Notch-mediated HES/HEY network DB_ID = 1457 C = 94; O = 3; E = 0.39; R = 7.73; rawP = 0.0070; adjP = 0.0120 Transport of inorganic DB_ID = 940 C = 94; O = 3; E = 0.39; R = 7.73; rawP = 0.0070; adjP = 0.0120 cations/anions and amino acids/oligopeptides Noncanonical Wnt signaling DB_ID = 1535 C = 182; O = 4; E = 0.75; R = 5.32; rawP = 0.0070; adjP = 0.0120 pathway Notch signaling pathway DB_ID = 1625 C = 94; O = 3; E = 0.39; R = 7.73; rawP = 0.0070; adjP = 0.0120 Signaling by Aurora kinases DB_ID = 1525 C = 98; O = 3; E = 0.40; R = 7.42; rawP = 0.0079; adjP = 0.0133 Interferon Signaling DB_ID = 1123 C = 98; O = 3; E = 0.40; R = 7.42; rawP = 0.0079; adjP = 0.0133 Regulation of gene expression in DB_ID = 61 C = 99; O = 3; E = 0.41; R = 7.34; rawP = 0.0081; adjP = 0.0134 beta cells Innate Immune System DB_ID = 1094 C = 190; O = 4; E = 0.78; R = 5.10; rawP = 0.0081; adjP = 0.0134 EPO signaling pathway DB_ID = 1555 C = 34; O = 2; E = 0.14; R = 14.25; rawP = 0.0087; adjP = 0.0143 Canonical NF-kappaB pathway DB_ID = 1450 C = 35; O = 2; E = 0.14; R = 13.84; rawP = 0.0092; adjP = 0.0149 PLK1 signaling events DB_ID = 1483 C = 104; O = 3; E = 0.43; R = 6.99; rawP = 0.0093; adjP = 0.0149 Signal transduction by L1 DB_ID = 27 C = 35; O = 2; E = 0.14; R = 13.84; rawP = 0.0092; adjP = 0.0149 Wnt signaling network DB_ID = 1435 C = 200; O = 4; E = 0.83; R = 4.85; rawP = 0.0097; adjP = 0.0154 Polo-like kinase signaling events DB_ID = 1528 C = 109; O = 3; E = 0.45; R = 6.67; rawP = 0.0105; adjP = 0.0165 in the cell cycle Glypican 3 network DB_ID = 1471 C = 206; O = 4; E = 0.85; R = 4.70; rawP = 0.0107; adjP = 0.0167 ErbB2/ErbB3 signaling events DB_ID = 1443 C = 38; O = 2; E = 0.16; R = 12.75; rawP = 0.0108; adjP = 0.0168 Syndecan-4-mediated signaling DB_ID = 1604 C = 209; O = 4; E = 0.86; R = 4.64; rawP = 0.0113; adjP = 0.0173 events PLC beta mediated events DB_ID = 487 C = 39; O = 2; E = 0.16; R = 12.42; rawP = 0.0114; adjP = 0.0173 p75 NTR receptor-mediated DB_ID = 252 C = 39; O = 2; E = 0.16; R = 12.42; rawP = 0.0114; adjP = 0.0173 signalling Platelet homeostasis DB_ID = 66 C = 40; O = 2; E = 0.17; R = 12.11; rawP = 0.0119; adjP = 0.0178 G-protein mediated events DB_ID = 488 C = 40; O = 2; E = 0.17; R = 12.11; rawP = 0.0119; adjP = 0.0178 Axon guidance DB_ID = 20 C = 219; O = 4; E = 0.90; R = 4.43; rawP = 0.0132; adjP = 0.0196 FOXA2 and FOXA3 transcription DB_ID = 1511 C = 43; O = 2; E = 0.18; R = 11.27; rawP = 0.0137; adjP = 0.0200 factor networks Signal Transduction DB_ID = 331 C = 1231; O = 11; E = 5.08; R = 2.17; rawP = 0.0137; adjP = 0.0200 Posttranslational regulation of DB_ID = 1512 C = 231; O = 4; E = 0.95; R = 4.20; rawP = 0.0157; adjP = 0.0226 adherens junction stability and dissassembly Presenilin action in Notch and DB_ID = 1621 C = 46; O = 2; E = 0.19; R = 10.53; rawP = 0.0156; adjP = 0.0226 Wnt signaling Interferon gamma signaling DB_ID = 1124 C = 47; O = 2; E = 0.19; R = 10.31; rawP = 0.0162; adjP = 0.0231 Alpha6Beta4Integrin DB_ID = 1660 C = 48; O = 2; E = 0.20; R = 10.10; rawP = 0.0169; adjP = 0.0240 Signaling mediated by p38-alpha DB_ID = 1524 C = 50; O = 2; E = 0.21; R = 9.69; rawP = 0.0182; adjP = 0.0256 and p38-beta Regulation of nuclear beta DB_ID = 1547 C = 135; O = 3; E = 0.56; R = 5.38; rawP = 0.0186; adjP = 0.0260 catenin signaling and target gene transcription SLC-mediated transmembrane DB_ID = 943 C = 248; O = 4; E = 1.02; R = 3.91; rawP = 0.0198; adjP = 0.0275 transport Platelet activation, signaling and DB_ID = 56 C = 139; O = 3; E = 0.57; R = 5.23; rawP = 0.0201; adjP = 0.0277 aggregation Opioid Signalling DB_ID = 486 C = 53; O = 2; E = 0.22; R = 9.14; rawP = 0.0203; adjP = 0.0278 Signalling by NGF DB_ID = 254 C = 143; O = 3; E = 0.59; R = 5.08; rawP = 0.0217; adjP = 0.0293 Metabolism DB_ID = 634 C = 824; O = 8; E = 3.40; R = 2.35; rawP = 0.0217; adjP = 0.0293 C-MYC pathway DB_ID = 1467 C = 149; O = 3; E = 0.61; R = 4.88; rawP = 0.0241; adjP = 0.0323 ATF-2 transcription factor network DB_ID = 1485 C = 59; O = 2; E = 0.24; R = 8.21; rawP = 0.0249; adjP = 0.0331 Fc-epsilon receptor I signaling in DB_ID = 1496 C = 61; O = 2; E = 0.25; R = 7.94; rawP = 0.0264; adjP = 0.0347 mast cells Coregulation of Androgen DB_ID = 1506 C = 61; O = 2; E = 0.25; R = 7.94; rawP = 0.0264; adjP = 0.0347 receptor activity Canonical Wnt signaling pathway DB_ID = 1542 C = 155; O = 3; E = 0.64; R = 4.69; rawP = 0.0267; adjP = 0.0348 Validated targets of C-MYC DB_ID = 1444 C = 63; O = 2; E = 0.26; R = 7.69; rawP = 0.0281; adjP = 0.0364 transcriptional repression Aurora A signaling DB_ID = 1646 C = 64; O = 2; E = 0.26; R = 7.57; rawP = 0.0289; adjP = 0.0372 Signaling by SCF-KIT DB_ID = 472 C = 66; O = 2; E = 0.27; R = 7.34; rawP = 0.0306; adjP = 0.0391 Downstream signaling in DB_ID = 1455 C = 67; O = 2; E = 0.28; R = 7.23; rawP = 0.0314; adjP = 0.0394 na&#xef; ve CD8+ T cells BCR signaling pathway DB_ID = 1513 C = 67; O = 2; E = 0.28; R = 7.23; rawP = 0.0314; adjP = 0.0394 RIG-I/MDA5 mediated induction DB_ID = 1115 C = 67; O = 2; E = 0.28; R = 7.23; rawP = 0.0314; adjP = 0.0394 of IFN-alpha/beta pathways Cell surface interactions at the DB_ID = 467 C = 72; O = 2; E = 0.30; R = 6.73; rawP = 0.0359; adjP = 0.0448 vascular wall Downstream signal transduction DB_ID = 467 C = 75; O = 2; E = 0.31; R = 6.46; rawP = 0.0386; adjP = 0.0478 Syndecan-2-mediated signaling DB_ID = 1581 C = 77; O = 2; E = 0.32; R = 6.29; rawP = 0.0405; adjP = 0.0496 events Interferon alpha/beta signaling DB_ID = 1122 C = 77; O = 2; E = 0.32; R = 6.29; rawP = 0.0405; adjP = 0.0496 Table 7a and Table 7b: Network statistics obtained from the PPI analysis in Dapple (a) and String (b). For Dapple, provided are the number of Exp (Expected), Obs (Observed), and permutation-derived P-values for the network statistic measures of connectivity. For String, O (observed) and E (expected) interactions and enrichment P-values (against a genome background) for candidate proteins encoded by (A) the GWS loci, (B) GWS and GWM loci, and (C) pAID candidate genes overlapping those in the JAK-STAT pathway.

A Dapple 27 GWS Loci (P < 5E−08) 46 GWM Loci (P < 1E−06) Network Statistics Obs Exp P - - - value Obs Exp P - - - value Direct Edges Count 8 3.47 1.73E−02 15 5.10 2.0E−04 Seed Direct Degrees Mean 1.78 1.15 2.23E−02 1.76 1.19 1.9E−02 Seed Indirect Degrees Mean 25.33 17.44 7.86E−02 22.16 17.20 1.2E−01 CI Degrees Mean 2.39 2.26 1.33E−01 2.53 2.30 7.4E−02

B String 27 GWS 46 GWM JAK-STAT PPI Proteins Considered 27 44 30 N interactions 26 48 50 E interactions 4.05 9.22 4.92 P-value 3.24E−13 <1.00E−20 <1.00E−20

TABLE 7c Significant pathways and biological processes enriched for pAID genes shared across DAVID, IPA, and GSEA. Biological pathways showing significant enrichment for candidate pAID associated genes identified by GBAT. Points correspond to P-values of each individual pathway database analysis method and are plotted in rank order as well as surrounded by gray boundary whose ordinate value corresponds to the Fisher meta-analysis score of the three pathways databases. Pathway Full Pathway Name GSEA IPA DAVID P_Fisher Stat Allo_rejection Allograft rejection 1.00E−05 2.00E−22 1.10E−21 2.61E−47 219.47 T1D Type I diabetes mellitus 1.00E−05 7.94E−15 3.39E−20 2.88E−38 177.62 AITD Autoimmune thyroid disease 1.00E−05 2.00E−17 8.12E−17 1.72E−37 174.03 GVHD Graft - - - versus - - - host disease 1.00E−05 1.00E−15 1.72E−16 1.77E−35 164.70 Antigen_proc Antigen processing and 1.00E−05 3.16E−25 5.77E−15 2.08E−43 201.43 presentation Asthma Asthma 1.00E−05 2.14E−06 1.94E−14 3.54E−24 112.28 Antigen_MHC_I Antigen processing and 1.00E−05 3.16E−25 7.80E−08 2.57E−36 168.59 presentation of peptide antigen via MHC class I Cytokine_Response Cytokines and Inflammatory 1.00E−05 6.03E−06 1.74E−05 7.05E−15 68.98 Response SLE Systemic lupus 4.83E−04 1.05E−02 6.16E−05 1.69E−09 43.77 erythematosus THl_TH2_Dif Th1/Th2 Differentiation 1.60E−04 2.51E−16 4.50E−04 1.49E−22 104.74 Cytokine_Net Cytokine Network 4.44E−05 6.03E−06 3.71E−03 6.00E−12 55.28 Innate_Response Positive regulation of innate 1.46E−03 4.79E−09 3.77E−02 1.63E−12 57.93 immune response

TABLE 8 List of phenotype abbreviations. THY Thyroiditis AS Spondyloarthropathy PS Psoriasis CEL Celiac Disease SLE Systemic Lupus Erythematosus CVID Common Variable Immunodeficiency UC Ulcerative Colitis T1D Type 1 Diabetes JIA Juvenile Idiopathic Arthritis CD Crohns Disease INF Inflammation BEH Behect's Disease MG Myasthenia Gravis PBC Primary Biliary Cirrhosis LEP Leprosy CRP C-Reactive Proteins VIT Vitiligo SCH Schizophrenia AST Asthma AUT Autism ALZ Alzheimer's END Endometriosis BPD Bipolar Disorder ALL Acute lymphocytic leukemia CLL Chronic lymphocytic leukemia LEL Liver Enzyme Levels PSC Primary Sclerosing cholangitis REN Renal Function Traits/Chronic Kidney Disease DER Dermatitis ADER Atopic Dermatitis D-NPH Diabetic Nephropathy NPH Nephropathy GRV Grave's AA Alopecia areata POS Polycystic ovarian syndrome HEMO Hemoglobin CJD Creutzfeldt-Jakob disease EPI Epilepsy RLS Restless Leg Syndrome TOU Tourette syndrome SAR Sarcoidosis CF Cystic Fibrosis VAS Vasculitis URL Urate Levels ANTC Anticoagulant Levels BIL Billirubin Levels RES Resistin levels EOS Eosinophil Levels APA antiphospholipid antibodies INS Insulin BAS Basophils CFCDNA Circulating Free Cell DNA GDM Gestational Diabetes ADPT Adiponectin FIB Fibrinogen PAN Pancreatitis DUD Dupuytren's disease NEU Neutrophil MNT Monocytes GLI Glioma NLUP Neonatal Lupus LYM Lymphocytes S-INF-A secreted IFN-alpha MPN Myeloproliferative neoplasms CAM Cell Adhesion Molecule HepC Hepatitis C AIDS autoimmune deficiency syndrome PAG Pagat's Disease MYLO Myloma GHEM glycohemoglobin GAU Gaucher disease CRC Colorectal Cancer Hematocrit/ GLA Heme/Hemostatic Factors/ Glaucoma SS Systemic Sclerosis ALS Amyotrophic lateral sclerosis MYO Myopia KAW Kawasaki PRI Prion disease KEL Keloid MET Metabolite Levels BAR Barrett's esophagus CKD Chronic kidney disease HLM Hodgkin's Lymphoma TSH Thyroid Stimulating Hormone NA None Available PAR Parkinson's Disease HEM Hematological phenotypes WTM Wilms Tumor SCO Scoliosis

TABLE 9a Genotyped subjects in the CHOP Biorepository eligible for this study. Total male female RACE WHITE 13918 7567 6351 BLACK OR AFRICAN 10179 5136 5043 AMERICAN OTHER 1718 929 789 ASIAN 433 208 225 AMERICAN INDIAN/ESKIMO/ 23 11 12 ALASKA NATIVE REFUSED 20 14 6 INDIAN 9 5 4 NATIVE HAWAIIAN/ 8 4 4 PACIFIC ISLANDER Total 26308 13874 12434 AGE (at recruitment) 18 1044 457 587 17 1277 558 719 16 1515 679 836 15 1490 696 794 14 1465 724 741 13 1453 719 734 12 1269 648 621 11 1205 619 586 10 1163 623 540  9 1179 640 539  8 1188 660 528  7 1097 623 474  6 1013 584 429  5 1188 661 527  4 1496 866 630  3 1996 1128 868  2 2117 1206 911  1 2514 1389 1125  0 643 398 245 Total 26312 13878 12434

TABLE 9b ICD9 diagnosis and search terms used to initially filter subjects based on CHOP EMRs. pAID ICD9 Search Terms and Codes ICD9 Search Terms and Codes THY %Chronic%Thyroiditis%|%Grave%|%Hashimoto%| 242.0%|245.0%|245.2% SPA %Ankyl%Spond%litis%|%Spondyloarthropathy%|720%| 720% PSOR %Psoriasis%|696.10% CEL %Celiac%|579.00% SLE %Systemic%Lupus%Erythematosus%|710.0% CVID %Variable%Immunodefi%|279.06% UC %Ulcerative%Colitis%|556% T1D %Type%1%Diabetes%|250._1%|250._3% JIA %Enthe%rthritis%|%Idiop%rthritis%|%Juvenile%rthritis%| %Mono%rthritis%|%Oligo%rthritis%|%Poly%rthritis%| %Psor%rthritis%|%Rheum%rthritis%|%System%Arthritis%| 714%|716.2%|716.5%|716.6%|716.8%|716.9% CD %Crohn%|555% NOTE: ICD9 codes used for EPIC-SQL case identification by patient diagnosis [% = wildcard (0 or more characters), _ = wildcard (exactly 1 character)]

References for Example I

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Example II Screening Assays for Identifying Efficacious Therapeutics for the Treatment of Aids

The information herein above can be applied clinically to patients for diagnosing an increased susceptibility for developing one or more AID (including pAIDs) and therapeutic intervention. An embodiment of the invention comprises clinical application of the information described herein to a patient. Diagnostic compositions, including microarrays, and methods can be designed to identify the SNPs described herein in nucleic acids from a patient to assess susceptibility for developing AID. This can occur after a patient arrives in the clinic; the patient has blood drawn, and using the diagnostic methods described herein, a clinician can detect a genetic alteration such as a single nucleotide polymorphism as described in Example I. The information obtained from the patient sample, which can optionally be amplified prior to assessment, may be used to diagnose a patient with an increased or decreased susceptibility for developing AID or used to direct treatment in a patient previously diagnosed with AID. Kits for performing diagnostic methods of the invention are also provided herein. Such kits may comprise a microarray comprising at least one of the SNVs/SNPs provided herein and the necessary reagents for assessing the patient samples as described above.

The identity of AID involved genes and the patient results will indicate which variants are present, and may be used to identify those that have, or possess an altered risk for developing AID. The information provided herein may allow for therapeutic intervention at earlier times in disease progression than previously possible. Also as described herein above, the genes listed in Supplemental Table 1b and provided the tables herein were shown to associate with one or more pAIDs at genome wide significance (GWS) levels, while an additional set (see Table 2b) were shown to associate with one or more pAIDs at genome wide marginal significance (GWM) levels, and these genes thus may provide a novel targets for the development of new therapeutic agents efficacious for the treatment of autoimmune disorders.

Example III Test and Treat Method for Ameliorating Symptoms Associated with AID

In order to treat an individual having AID (including pAID), for example, to alleviate a sign or symptom of the disease, suitable agents targeting the genes disclosed in the tables herein can be administered in combination in order to provide therapeutic benefit to the patient. Such agents should be administered in an effective dose.

First, a biological sample, or genotyping information would be obtained from a patient. Genetic information gleaned from nucleic acids present in the sample would then be assessed for the presence or absence of the AID SNV/SNP containing nucleic acids associated with onset of one or more AID. The presence of these SNVs indicating the presence of an AID, along with the simultaneous identification of the genes affected, providing the clinician with guidance as to which therapeutic agents are appropriate. The total treatment dose or doses (when two or more targets are to be modulated) can be administered to a subject as a single dose or can be administered using a fractionated treatment protocol, in which multiple/separate doses are administered over a more prolonged period of time, for example, over the period of a day to allow administration of a daily dosage or over a longer period of time to administer a dose over a desired period of time. One skilled in the art would know that the amount of AID agent required to obtain an effective dose in a subject depends on many factors, including the age, weight and general health of the subject, as well as the route of administration and the number of treatments to be administered. In view of these factors, the skilled artisan would adjust the particular dose so as to obtain an effective dose for treating an individual having AID.

The effective dose of AID therapeutic agent(s) will depend on the mode of administration, and the weight of the individual being treated. The dosages described herein are generally those for an average adult but can be adjusted for the treatment of children. The dose will generally range from about 0.001 mg to about 1000 mg.

In an individual suffering from AID, in particular a more severe form of the disease, administration of AID therapeutic agents can be particularly useful when administered in combination, for example, with a conventional agent for treating such a disease. The skilled artisan would administer AID therapeutic agent(s), alone or in combination and would monitor the effectiveness of such treatment using routine methods such as pulmonary, bowel, thryroid, inflammatory function determination, radiologic, immunologic assays, or, where indicated, histopathologic methods. Other conventional agents for the treatment of AID include steroid or administration of other agents that alleviate the symptoms underlying the disease.

Administration of the pharmaceutical preparation is preferably in an “effective amount” this being sufficient to show benefit to the individual. This amount prevents, alleviates, abates, or otherwise reduces the severity of at least one AID symptom in a patient.

In a preferred embodiment of this invention, a method is provided for the synergistic treatment of AID using the pharmaceutical agents disclosed in the present example in combinatorial approaches. Advantageously, the synergistic method of this invention reduces the development of AID, or reduces symptoms of AID in a mammalian host. Additionally, therapeutic regimens suitable for simultaneous treatment of two or more AID disorders are also provided. As shown in the tables, certain genes appear to modulate the autoimmune phenotypes in more than one pAID. Moreover, it is known that certain patients present with more than one AID in the clinic. The information provided herein guides the clinician in new treatment modalities for the management of AID.

Methods for the safe and effective administration of FDA-approved pharmaceutical agents are known to those skilled in the art. In addition, their administration is described in the standard literature. For example, the administration of many anti-inflammatory agents is described in the “Physicians' Desk Reference” (PDR), e.g., 1996 edition (Medical Economics Company, Montvale, N.J. 07645-1742, USA); the disclosure of which is incorporated herein by reference thereto.

The present invention also encompasses a pharmaceutical composition useful in the treatment of AID, comprising the administration of a therapeutically effective amount of the combinations of this invention, with or without pharmaceutically acceptable carriers or diluents. The synergistic pharmaceutical compositions of this invention comprise two or more of the agents listed in the table below and a pharmaceutically acceptable carrier. The compositions of the present invention may further comprise one or more pharmaceutically acceptable additional ingredient(s) such as alum, stabilizers, antimicrobial agents, buffers, coloring agents, flavoring agents, adjuvants, and the like. The anti-AID compositions of the present invention may be administered orally or parenterally including the intravenous, intramuscular, intraperitoneal, subcutaneous, rectal and topical routes of administration.

Determination of the proper dosage for a particular situation is within the skill of the art. Generally, treatment is initiated with smaller dosages which are less than the optimum dose of the compound. Thereafter, the dosage is increased by small amounts until the optimum effect under the circumstances is reached. For convenience, the total daily dosage may be divided and administered in portions during the day if desired. Intermittent therapy (e.g., one week out of three weeks or three out of four weeks) may also be used.

Certain AIDs can be treated effectively with a plurality of the compounds listed above. Such triple and quadruple combinations can provide greater efficacy. When used in such triple and quadruple combinations the dosages can be determined according to known protocols.

The combinations of the instant invention may also be co-administered with other therapeutic agents selected for their particular usefulness against the condition that is being treated. Combinations of the instant invention may alternatively be used sequentially with known pharmaceutically acceptable agent(s) when a multiple combination formulation is inappropriate.

Also, in general, the compounds listed above do not have to be administered in the same pharmaceutical composition, and may, because of different physical and chemical characteristics, have to be administered by different routes. For example, first compound may be administered orally to generate and maintain good blood levels thereof, while a second compound may be administered intravenously. The determination of the mode of administration and the advisability of administration, where possible, in the same pharmaceutical composition, is well within the knowledge of the skilled clinician. The initial administration can be made according to established protocols known in the art, and then, based upon the observed effects, the dosage, modes of administration and times of administration can be modified by the skilled clinician.

As described previously in Example I, genome wide association studies (GWAS) have identified hundreds of susceptibility genes associated with autoimmune diseases with some shared across clinically-distinct disease groups. To investigate the genetic architecture of pediatric autoimmune diseases (pAIDs), we performed a heterogeneity-sensitive GWAS (hsGWAS) across 10 pAIDs in a nested case-control study including over 5,200 cases and 11,000 controls (Table 10). We identified 86 independent pAID association loci (P<5×10⁻⁸) (See Tables herein below), including genes with established immunoregulatory functions (e.g., CD40LG; P<3.08×10⁻¹¹ and NFATC3; P<1.18×10⁻⁸). Of those, 97% were supported by functional (n=30), regulatory (n=55), conservational (n=30) or literature-reported (n=40) data, and demonstrated disease-specific gene expression patterns across specific immune cell lineages. Integration of multiple in silico analytical approaches identified highly shared autoimmune signals (e.g., IL2-IL21 P<6.24×10⁻¹²) and converging roles for JAK-STAT, innate, and TH1-TH2/TH17 mediated T-cell signaling among attractive pharmacological targets involving pAID biology. Targets with known drugs available are shown in Tables 11 and 12. These drugs can be combined to synergistically treat pAID or to simultaneously reduce symptoms or progression of multiple pAIDs (2-5 separate pAIDs) as shown in Tables 11 and 12 below. The numbers in the last column of Table 11 correspond to the subtype of pAID listed in Table 10.

TABLE 10 Cohort characteristics of the ten pediatric autoimmune disease patient cohorts Genomic F:M Inflation Abbrev. Subtype^(a) pAID Count Ratio (λ)^(d) THY 1 Thyroiditis 99 0.758 1.004 SPA 2 Spondyloarthropathy 111 0.550 1.012 PSOR 3 Psoriasis 113 0.584 1.001 CEL 4 Celiac Disease 183 0.632 1.025 SLE 5 Systemic Lupus Erythematosus 256 0.877 1.022 CVID 6 Common Variable 309 0.542 1.038 Immundeficiency UC 7 Ulcerative Colitis 895 .0542 1.038 T1D 8 Type 1 Diabetes 1139 0.486 1.037 JIA 9 Juvenile Idiopathic Arthritis 1165 0.687 1.009 CD 10 Crohn's Disease 2039 0.422 1.089 CTRL 0 Non-AID Ascertained Controls 11179 0.479 — Classical GWAS All Al disease cases merged 5589 0.464 1.026^(e) Method hsGWAS All Al disease cases non- 5589 0.464 1.061^(f) Method overlapping ^(a)pAID abbreviations correspond to and are cross-referenced in Table 1B, 1C and 2A b) Case counts are those from the respective pAID cohorts after all QC and filtering c) Controls were ascertained based on EMR records showing no diagnosis for ICD9 codes across all immune-mediated (autoimmune, immunodeficiency, and inflammatory) diseases ^(d)Genomic inflation (λ) was calculated based on single disease case-(shared) control association analysis summary statistics ^(e)Mean λ across the ten respective classic GWAS studies ^(f)Adjusted for a 1000-case-100-control cohort size, excluding MHC; see supplemental methods

TABLE 11 (Numbers listed in last column correspond to pAID listed in Table 10 above.) Entrez Gene SNP- Cellular Gene Name Chr Start Stop Pvalue Best-5NP pvalue Location Protein Type Drug pAIDs PLA2G4A Phospholipase 1 185064654 185224736 <1 × 10−6 rs932476 2.3844E−07 Cytoplasm enzyme Quinacrine A003 AK106 ASB14780 3|4|7|10 A2, group IVA AVX001 AVX002 AVX003 AVX235 (cytosolic, Bactoderm C Bactoderm GM Bactoderm N calcium- Bestasol Bet-Vet-N Betnogard C Betval-C dependent) BL3030 CB24 Clobetasol SAVA cPLA2 Inhibitors MERCKLE Fenspiride FARMAPROJECTS Fenspogal Inzitan IPP201007 IS741 Lifuzon LY315920 LY333013 Momesone PO-LING MRX4 MRX5 MRX6 OPX1 PLA695 PLA725 PLA902 Pulneo SKMS10 Tirfens Topidin Troxerutin SYNTEZA VRCTC310 ZPL5212372 MST1R Macrophage 3 49899439 49916310 <1 × 10−6 rs2246832 3.5048E−09 Plasma kinase Crizotinib AL2846 Anti-RON antibody 3|4|7|10 stimulating 1 Membrane ABZYME Anti-RON proteolytic antibody receptor (c-met- ABZYME Anti-RONXAnti-CD3 EMERGENT related tyrosine IMC41A10 IMCRON8 Kinase Inhibitors kinase) MIRATI MGCD265 RON Receptor Monoclonal Antibody AVEO IL13 Interleukin 13 5 132021763 132024700 <1 × 10−6 Rs2227284 2.4747E−08 Extracellular ctyokine CAT-354 GSK679586 IL-4/IL-13 2|3|10 Space Inhibiting Peptide SYNAIRGEN IMA026 MEDI7836 MILR1444A QAX576 QBX258 R256 IL12B Interleukin 12B 5 158674368 158690059 <1 × 10−6 rs4921484 6.9104E−12 Extracellular ctyokine Ustekinumab; Ad-IL12 1|3|4|7|10 (natural killer cell Space Immunogene Therapy stimulatory factor MOMOTARO 2, cytotoxic lymphocyte maturation factor 2, p40) GABBR1 Gamma- 6 29677983 29708941 <1 × 10−6 rs2071653 2.87275E−08  Plasma G-protein baclofen, vigabatrin ADX71943 4|6|8|10 aminobutyric acid Membrane coupled ADX71441 AMRS001 Aero-Itan (GABA) 8 receptor Ansielix Digest Apo-Chlorax receptor, 1 AwaLibrin Baby-tal Belladona alkaloids with Phenobarbital WEST WARD Belladonna alkaloids W/Phenobarbital Bralix Braxidin Chlordiazepoxide hydrochloride with Clidinium bromide ACTAVIS Chlordiazepoxide hydrochloride with Clidinium bromide QUALITEST Chlorspas Cibis Cliad Clidinium-C Clidinium-C HAKIM Clidinium-C ZAHRAVI Clidox M Clidox MORACEAE Clixid-D Cloxide Coliwin Tablets CVXL0060 Cylospas Debridat B Distedon Donnatal Epirax Euciton Stress Eudon Eumotil-T Faradil Faradil Novo Laberax Lebraxim Libkol Liblan Librax Librax COMBIPHAR Libtrax Malzorir Mebeverine hydrochloride with Alprazolam STERLING No-Ref Normaxin Normaxin RT Normib Pasminox Somatico Pipdole Piplar Poxidium Profisin Ranicom-AS Renagas Sinpasmon Spasrax Spaz-CD Tensium Gastric Ulic Vertipam Zibra PF0713 TNF Tumor necrosis 6 31651328 31654091 <1 × 10−6 rs2269475 6.9605E−11 Extracellular cytokine etanercept, infliximab, certolizumab, 2|3|5|8|9 factor Space golimumab, pomalidomide, thalidomide; Remicade Humera F45D9 Apocept Enbrel GWP42003 Revlimid TACIFc5 Atrosab Genz29155 KAHR101 PUR0110 Onercept Cinzia Rensima CEP37247 DLX105 ABP501 ACE772 BM02 CHS0214 Etanercept Infinitam ISIS104838 Tinefcon TuNEX Nanercpt AG014 ATB429 BTI9 CB0112 HMPL004 Humicade LexaGard SAR252067 TAK114 UR12746S ATN103 Infliximab MDR06155 Simponi Shinbaro CC1088 KIN219 AVX470 Prolia ABP710 ABT122 Adalimumab ALKS6931 Altebrel AMAB Anbainuo APG103 APX001 OX40 Ligand Monoclonal Ab Pegsunercept PF06410293 PF06438179 CHRONTECH ORCHID SAREPTA PROTELICA ANTYRA EDEXGEN Xtend-TNF ENSEMBLE TNFPEG20 TriptoSar Xgeva ONL101 ONL1204 OPK20018 Recombinant Human Nerve Growth Factor DOMPE Dom0101 GSK1995057 GSK2862277 RG4930 HLA-DRB1 Major 6 32654524 32665540 <1 × 10−6 rs9271366 2.37686E−42  Plasma Transmembrane Apolizumab; Anti-HLA-DR (DENDREON) 6|8 histocompatibility Membrane receptor CAP31 CD79BxDR Dantes DN1924 complex, class HLA-DQ2 Blockers ALVINE IMMU114 II, DR beta 1 Remitogen PSMB9 Proteasome 6 32929915 32935606 <1 × 10−6 rs241407 3.21942E−27  Cytoplasm peptidase Carfilzomib 1|8 (prosome, macropain) subunit, beta type, 9 COL11A2 Collagen, type XI, 6 33238446 33268223 <1 × 10−6 rs1977090 6.68314E−13  Extracellular other collagenase clostridium histolyticum 8 alpha 2 Space ABT518; Abbott IL2RA Interleukin 2 10 6093511 6144278 <1 × 10−6 rs12722563 3.5412E−11 Plasma Transmembrane LMB-2, daclizumab, basilliximab, 3|6|7|8|9 receptor, alpha Membrane receptor aldesleukin, denileukin diftitox; ADCT301 TH Tyrosine 11 2141734 2149611 <1 × 10−6 rs3842727 1.4786E−38 Cytoplasm enzyme 5,6,7,8-tetrahydrobiopterin Demser 8 hydroxylase OXB102 Parkinson Gene Therapy SHIRE Prosavin CDK2 Cyclin-dependent 12 54646822 54652835 <1 × 10−6 rs772921 3.3821E−13 Nucleus kinase BMS-387032, flavopiridol; AG24322 3|8 kinase 2 Pfizer ERBB3 v-erb-b2 avian 12 54760158 54783395 <1 × 10−6 rs705704 1.5348E−12 Plasma kinase Sapitinib; AV203 3|8 erythroblastic Membrane leukemia viral oncogene homolog 3 PSMB10 Proteasome 16 66525907 66528254  1 × 10−6 rs3785098 1.6024E−08 Cytoplasm peptidase Carflizomib ARRY520 Bitezo Bortecad 5|6|8 (prosome, Bortemib Bortenat NATCO Bortenat macropain) RADIANCE Bortezomib ACCURE Bortezomib subunit, beta ACTAVIS Bortezomib ADMAC Bortezomib type, 10 HETERO Bortezomib Micelle NANOCARRIER Bortezomib NAPROD Bortezomib NERVIANO Bortezomib SALIUS Bortezomib SAVA Bortezomib SYNCHRONY Bortezomib TEVA Bortezomib UNITED BIOTECH Bortiad Bortrac Borviz BT062 CEP18770 CEP28331 DSF-C Fellutamide C and D MERCK FV162 FV214 HIV 26S Proteasome Inhibitor VIROLOGIK IAV Proteasome Inhibitor VIROLOGIK Kyprolis Mibor Milanfor MLN273 MLN519 MLN9708 Myezom Mylosome NEOSH101 NOXA12 NPI0052 Oncodox Peg with Bortezomib CIPLA ONX0912 ONX0914 Ortez PR924 Proteasome inhibitor JEIL Proteasome Inhibitors MABVAX Proteasome Inhibitors QUIMATRYX Rolcade Tazenta Tetra-acridines PIERRE FABRE Velcade VL01 VLX1570 VPE001 VPEA002 VPEA004 VR23 Zolinza SLC12A4 Solute carrier 16 66535730 66560026 <1 × l0−6  rs3785098 1.6024E−08 Plasma transporter Butetanide; CL301 CLP290 5|6|8 family 12 Membrane CLP635 Reformulated Bumetanide (potassium/chloride transporter), member 4

TABLE 12 Certain Molecules in Development Associated with Particular Genes Gene Therapeutic Molecules on U.S. Market or in Development CD40LG Anti-CD40LG antibodies (e.g. BMS986004; dapirolizumab (CDP7657); toralizumab (IDEC131)); CD40 antibodies (e.g. BI655064); CD40LG inhibitors (e.g. PEPSCAN); MEDI4920; TDI846 LRRK2 LRRK2 inhibitors (e.g. ARN1104; H1337) IL-21 Anti-IL21 antibodies (e.g. NN8828); KD025; ATR107; BNZ2; BNZ3 ADCY7 ACP003; Adehl; Corgenic; NKH477; RT100; Type 5 Adenylyl Cyclase Inhibitors SMAD3 GED0301 NOD2 Mifamurtide (Mepact ™); MIS416; SB9200 IL2RA Recombinant IL2 (e.g. Aldesleukin; ligen-2; Inleusin ™; Interking ™); inolimomab (BLNP007 or BT563); anti-IL2RA antibody (HuMax-TAC); MDNA12; dinutuximab; LMB-2; basilliximab; denileukin diftitox; ADCT301

While certain of the preferred embodiments of the present invention have been described and specifically exemplified above, it is not intended that the invention be limited to such embodiments. Various modifications may be made thereto without departing from the scope and spirit of the present invention, as set forth in the following claims. 

What is claimed is:
 1. A method for detecting a single nucleotide variation (SNV) in rs2807264 on Xq26.3 in CD40LG in a celiac disease (CEL), ulcerative colitis (UC), or Crohn's disease (CD) human patient comprising: a) obtaining a biological sample from the human patient; and b) detecting a single nucleotide variation (SNV) in rs2807264 nucleic acid on Xq26.3 by contacting the sample with a probe specific for said SNV and detecting binding between said probe and said SNV nucleic acid.
 2. The method of claim 1, wherein the method further comprises detecting a single nucleotide variation (SNV) in at least one of IL23R, LPHN2, PTPN22, TNFSF18, CRB1, IL10, TSSC1, IL18R1, ATG16L1, GPR35, DAG1, CYTL1, IL21, TNM3, PTGER4, ANKRD55, ERAP2, IL5, IL12B, 8q24.23, JAK2, LURAP1L, TNFSF15, FNBP1, CARDS, IL2RA, ANKRD30A, ZNF365, ZMIZ1, NKX2-3, INS, LRRK2, SUOX, EFNB2, SMAD3, SBK1, ATXN2L, ADCY7, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, PSMG1, and RBMX.
 3. The method of claim 1, wherein the patient is a pediatric patient.
 4. The method of claim 1, wherein the method comprises treating UC, or CEL or CD by administering an anti-CD40LG antibody, CD40 antibody, or CD40LG inhibitor to the patient.
 5. The method of claim 1, wherein the method further comprises detecting a single nucleotide variation (SNV) in one or more of LPHN2, TNM3, and ADCY7.
 6. The method claim 4, wherein the method comprises treating ulcerative colitis (UC) and further comprises detecting a single nucleotide variation (SNV) in one or more of IL23R, LPHN2, DAG1, PTGER4, SBK1, TNFSF15, CD40LG, IL21, CARD9, and PSMG1.
 7. The method of claim 6, wherein the method further comprises detecting a single nucleotide variation (SNV) in one or more of IL10, TSSC1, IL18R1, GPR35, CYTL1, IL12B, JAK2, NKX2, SMAD3, ATXN2L, IKZF3, and TNFRSF6B.
 8. The method of claim 4, wherein the method comprises treating Crohn's Disease (CD) and further comprises detecting a single nucleotide variation (SNV) in one or more of IL23R, PTPN22, DAG1, ATG16L1, PTGER4, ANKRD55, LRRK2, SBK1, ADCY7, IL2RA, TNFSF15, ZMIZ1, IL21, CARD9, and PSMG1.
 9. The method of claim 8, wherein the method further comprises detecting a single nucleotide variation (SNV) in one or more of CRB1, IL10, TSSC1, IL18R1, CYTL1, ERAP2, IL5, IL12B, 8q24.23, JAK2, FNBP1, ZNF365, NKX2, SMAD3, ATXN2L, NOD2, IKZF3, TYK2, FUT2, TNFRSF6B, and RBMX.
 10. The method of claim 1, wherein the method comprises detecting a single nucleotide variation (SNV) in one or more of PTPN22, TNM3, SBK1, IL2RA, and IL21.
 11. The method of claim 10, wherein the method further comprises detecting a single nucleotide variation (SNV) in one or more of IL18R1, CYTL1, FNBP1, IKZF3, TYK2, and TNFRSF6B is present.
 12. The method of claim 4, wherein the method comprises treating Celiac Disease (CEL) and further comprises detecting a single nucleotide variation (SNV) in one or more of TNM3, DAG1, SBK1, IL2RA, ZMIZ1, or IL21.
 13. The method of claim 12, wherein the method further comprises detecting a single nucleotide variation (SNV) in one or more of IL18R1, CYTL1, ERAP2, IL5, IL12B, 8q24.23, IKZF3, or RBMX. 